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.. _highlevel:
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High-level overview
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===================
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Structure
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----------
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The general structure is driven by the usage of interfaces provided by objects.
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The FSFW uses C++11 as baseline. The intention behind this is that this C++ Standard should be
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widely available, even with older compilers.
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The FSFW uses dynamic allocation during the initialization but provides static containers during runtime.
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This simplifies the instantiation of objects and allows the usage of some standard containers.
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Dynamic Allocation after initialization is discouraged and different solutions are provided in the
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FSFW to achieve that. The fsfw uses run-time type information but exceptions are not allowed.
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Failure Handling
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-----------------
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Functions should return a defined :cpp:type:`ReturnValue_t` to signal to the caller that something has
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gone wrong. Returnvalues must be unique. For this the function :cpp:func:`HasReturnvaluesIF::makeReturnCode`
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or the :ref:`macro MAKE_RETURN_CODE <retvalapi>` can be used. The ``CLASS_ID`` is a unique ID for that type of object.
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See the :ref:`FSFW Class IDs file <fwclassids>`. The user can add custom ``CLASS_ID``\s via the
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``fsfwconfig`` folder.
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OSAL
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------------
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The FSFW provides operation system abstraction layers for Linux, FreeRTOS and RTEMS.
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The OSAL provides periodic tasks, message queues, clocks and semaphores as well as mutexes.
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The :ref:`OSAL README <osal>` provides more detailed information on provided components
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and how to use them.
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Core Components
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----------------
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The FSFW has following core components. More detailed informations can be found in the
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:ref:`core component section <core>`:
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1. Tasks: Abstraction for different (periodic) task types like periodic tasks or tasks
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with fixed timeslots
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2. ObjectManager: This module stores all `SystemObjects` by mapping a provided unique object ID
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to the object handles.
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3. Static Stores: Different stores are provided to store data of variable size (like telecommands
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or small telemetry) in a pool structure without using dynamic memory allocation.
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These pools are allocated up front.
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4. Clock: This module provided common time related functions
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5. EventManager: This module allows routing of events generated by `SystemObjects`
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6. HealthTable: A component which stores the health states of objects
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Static IDs in the framework
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--------------------------------
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Some parts of the framework use a static routing address for communication.
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An example setup of IDs can be found in the example config in ``misc/defaultcfg/fsfwconfig/objects``
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inside the function ``Factory::setStaticFrameworkObjectIds``.
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Events
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----------------
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Events are tied to objects. EventIds can be generated by calling the
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:ref:`macro MAKE_EVENT <eventapi>` or the function :cpp:func:`event::makeEvent`.
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This works analog to the returnvalues. Every object that needs own Event IDs has to get a
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unique ``SUBSYSTEM_ID``. Every :cpp:class:`SystemObject` can call
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:cpp:func:`SystemObject::triggerEvent` from the parent class.
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Therefore, event messages contain the specific EventId and the objectId of the object that
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has triggered.
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Internal Communication
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-------------------------
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Components communicate mostly via Messages through Queues.
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Those queues are created by calling the singleton ``QueueFactory::instance()->create`` which
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will create `MessageQueue` instances for the used OSAL.
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External Communication
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--------------------------
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The external communication with the mission control system is mostly up to the user implementation.
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The FSFW provides PUS Services which can be used to but don't need to be used.
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The services can be seen as a conversion from a TC to a message based communication and back.
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TMTC Communication
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~~~~~~~~~~~~~~~~~~~
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The FSFW provides some components to facilitate TMTC handling via the PUS commands.
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For example, a UDP or TCP PUS server socket can be opened on a specific port using the
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files located in ``osal/common``. The FSFW example uses this functionality to allow sending
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telecommands and receiving telemetry using the
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`TMTC commander application <https://github.com/robamu-org/tmtccmd>`_.
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Simple commands like the PUS Service 17 ping service can be tested by simply running the
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``tmtc_client_cli.py`` or ``tmtc_client_gui.py`` utility in
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the `example tmtc folder <https://egit.irs.uni-stuttgart.de/fsfw/fsfw_example_public/src/branch/master/tmtc>`_
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while the `fsfw_example` application is running.
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More generally, any class responsible for handling incoming telecommands and sending telemetry
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can implement the generic ``TmTcBridge`` class located in ``tmtcservices``. Many applications
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also use a dedicated polling task for reading telecommands which passes telecommands
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to the ``TmTcBridge`` implementation.
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CCSDS Frames, CCSDS Space Packets and PUS
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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If the communication is based on CCSDS Frames and Space Packets, several classes can be used to
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distributed the packets to the corresponding services. Those can be found in ``tcdistribution``.
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If Space Packets are used, a timestamper has to be provided by the user.
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An example can be found in the ``timemanager`` folder, which uses ``CCSDSTime::CDS_short``.
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Device Handlers
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--------------------------
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DeviceHandlers are another important component of the FSFW. The idea is, to have a software
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counterpart of every physical device to provide a simple mode, health and commanding interface.
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By separating the underlying Communication Interface with
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``DeviceCommunicationIF``, a device handler (DH) can be tested on different hardware.
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The DH has mechanisms to monitor the communication with the physical device which allow
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for FDIR reaction. Device Handlers can be created by implementing ``DeviceHandlerBase``.
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A standard FDIR component for the DH will be created automatically but can
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be overwritten by the user. More information on DeviceHandlers can be found in the
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related [documentation section](doc/README-devicehandlers.md#top).
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Modes and Health
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--------------------
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The two interfaces ``HasModesIF`` and ``HasHealthIF`` provide access for commanding and monitoring
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of components. On-board mode management is implement in hierarchy system.
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- Device handlers and controllers are the lowest part of the hierarchy.
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- The next layer are assemblies. Those assemblies act as a component which handle
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redundancies of handlers. Assemblies share a common core with the top level subsystem components
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- The top level subsystem components are used to group assemblies, controllers and device handlers.
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For example, a spacecraft can have a atttitude control subsystem and a power subsystem.
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Those assemblies are intended to act as auto-generated components from a database which describes
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the subsystem modes. The definitions contain transition and target tables which contain the DH,
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Assembly and Controller Modes to be commanded.
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Transition tables contain as many steps as needed to reach the mode from any other mode, e.g. a
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switch into any higher AOCS mode might first turn on the sensors, than the actuators and the
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controller as last component.
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The target table is used to describe the state that is checked continuously by the subsystem.
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All of this allows System Modes to be generated as Subsystem object as well from the same database.
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This System contains list of subsystem modes in the transition and target tables.
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Therefore, it allows a modular system to create system modes and easy commanding of those, because
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only the highest components must be commanded.
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The health state represents if the component is able to perform its tasks.
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This can be used to signal the system to avoid using this component instead of a redundant one.
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The on-board FDIR uses the health state for isolation and recovery.
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