Merge branch 'development' into mueller/timeman-update

This commit is contained in:
Steffen Gaisser 2020-12-22 15:36:48 +01:00
commit fe26fc4824
8 changed files with 158 additions and 106 deletions

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@ -53,6 +53,12 @@ ID for now.
- There is an additional `PERFORM_OPERATION` step for the device handler base. It is important
that DHB users adapt their polling sequence tables to perform this step. This steps allows for aclear distinction between operation and communication steps
- setNormalDatapoolEntriesInvalid is not an abstract method and a default implementation was provided
- getTransitionDelayMs is now an abstract method
### DeviceHandlerIF
- Typo for UNKNOWN_DEVICE_REPLY
### Events

100
README.md
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@ -1,4 +1,5 @@
![FSFW Logo](logo/FSFW_Logo_V3_bw.png)
# Flight Software Framework (FSFW)
The Flight Software Framework is a C++ Object Oriented Framework for unmanned,
@ -14,83 +15,54 @@ The framework is designed for systems, which communicate with external devices,
Therefore, a mode and health system provides control over the states of the software and the controlled devices.
In addition, a simple mechanism of event based fault detection, isolation and recovery is implemented as well.
The recommended hardware is a microprocessor with more than 2 MB of RAM and 1 MB of non-volatile Memory.
The recommended hardware is a microprocessor with more than 1 MB of RAM and 1 MB of non-volatile Memory.
For reference, current Applications use a Cobham Gaisler UT699 (LEON3FT), a ISISPACE IOBC or a Zynq-7020 SoC.
The `fsfw` was also tested on the STM32H743ZI-Nucleo board.
## How to Use
The [FSFW example](https://egit.irs.uni-stuttgart.de/fsfw/fsfw_example) provides a good starting point and a demo
to see the FSFW capabilities and build it with the Make or the CMake build system.
Generally, the FSFW is included in a project by compiling the FSFW sources and providing
a configuration folder and adding it to the include path.
A template configuration folder was provided and can be copied into the project root to have
a starting point. The [configuration section](doc/README-config.md#top) provides more specific information about
the possible options.
## Structure
The general structure is driven by the usage of interfaces provided by objects. The FSFW uses C++11 as baseline. The intention behind this is that this C++ Standard should be widely available, even with older compilers.
The general structure is driven by the usage of interfaces provided by objects.
The FSFW uses C++11 as baseline. The intention behind this is that this C++ Standard should be widely available, even with older compilers.
The FSFW uses dynamic allocation during the initialization but provides static containers during runtime.
This simplifies the instantiation of objects and allows the usage of some standard containers.
Dynamic Allocation after initialization is discouraged and different solutions are provided in the FSFW to achieve that.
The fsfw uses Run-time type information.
Exceptions are not allowed.
The fsfw uses run-time type information but exceptions are not allowed.
### Failure Handling
Functions should return a defined ReturnValue_t to signal to the caller that something is gone wrong.
Functions should return a defined ReturnValue_t to signal to the caller that something has gone wrong.
Returnvalues must be unique. For this the function HasReturnvaluesIF::makeReturnCode or the Macro MAKE_RETURN can be used.
The CLASS_ID is a unique id for that type of object. See returnvalues/FwClassIds.
### OSAL
The FSFW provides operation system abstraction layers for Linux, FreeRTOS and RTEMS. A independent OSAL called "host" is currently not finished. This aims to be running on windows as well.
The OSAL provides periodic tasks, message queues, clocks and Semaphores as well as Mutexes.
The FSFW provides operation system abstraction layers for Linux, FreeRTOS and RTEMS.
A independent Host OSAL is in development which will provide abstraction for common type of
host OSes (tested for Linux and Windows, not for MacOS yet).
The OSAL provides periodic tasks, message queues, clocks and semaphores as well as mutexes.
### Core Components
Clock:
* This is a class of static functions that can be used at anytime
* Leap Seconds must be set if any time conversions from UTC to other times is used
ObjectManager (must be created):
* The component which handles all references. All SystemObjects register at this component.
* Any SystemObject needs to have a unique ObjectId. Those can be managed like objects::framework_objects.
* A reference to an object can be get by calling the following function. T must be the specific Interface you want to call.
A nullptr check of the returning Pointer must be done. This function is based on Run-time type information.
``` c++
template <typename T> T* ObjectManagerIF::get( object_id_t id )
```
* A typical way to create all objects on startup is a handing a static produce function to the ObjectManager on creation.
By calling objectManager->initialize() the produce function will be called and all SystemObjects will be initialized afterwards.
Event Manager:
* Component which allows routing of events
* Other objects can subscribe to specific events, ranges of events or all events of an object.
* Subscriptions can be done during runtime but should be done during initialization
* Amounts of allowed subscriptions must be configured by setting this parameters:
``` c++
namespace fsfwconfig {
//! Configure the allocated pool sizes for the event manager.
static constexpr size_t FSFW_EVENTMGMR_MATCHTREE_NODES = 240;
static constexpr size_t FSFW_EVENTMGMT_EVENTIDMATCHERS = 120;
static constexpr size_t FSFW_EVENTMGMR_RANGEMATCHERS = 120;
}
```
Health Table:
* A component which holds every health state
* Provides a thread safe way to access all health states without the need of message exchanges
Stores
* The message based communication can only exchange a few bytes of information inside the message itself. Therefore, additional information can be exchanged with Stores. With this, only the store address must be exchanged in the message.
* Internally, the FSFW uses an IPC Store to exchange data between processes. For incoming TCs a TC Store is used. For outgoing TM a TM store is used.
* All of them should use the Thread Safe Class storagemanager/PoolManager
Tasks
There are two different types of tasks:
* The PeriodicTask just executes objects that are of type ExecutableObjectIF in the order of the insertion to the Tasks.
* FixedTimeslotTask executes a list of calls in the order of the given list. This is intended for DeviceHandlers, where polling should be in a defined order. An example can be found in defaultcfg/fsfwconfig/pollingSequence
The FSFW has following core components. More detailed informations can be found in the
[core component section](doc/README-core.md#top):
1. Tasks: Abstraction for different (periodic) task types like periodic tasks or tasks with fixed timeslots
2. ObjectManager: This module stores all `SystemObjects` by mapping a provided unique object ID to the object handles.
3. Static Stores: Different stores are provided to store data of variable size (like telecommands or small telemetry) in a pool structure without
using dynamic memory allocation. These pools are allocated up front.
3. Clock: This module provided common time related functions
4. EventManager: This module allows routing of events generated by `SystemObjects`
5. HealthTable: A component which stores the health states of objects
### Static Ids in the framework
@ -121,13 +93,15 @@ If the communication is based on CCSDS Frames and Space Packets, several classes
If Space Packets are used, a timestamper must be created.
An example can be found in the timemanager folder, this uses CCSDSTime::CDS_short.
#### DeviceHandling
#### Device Handlers
DeviceHandlers are a core component of the FSFW.
DeviceHandlers are another important component of the FSFW.
The idea is, to have a software counterpart of every physical device to provide a simple mode, health and commanding interface.
By separating the underlying Communication Interface with DeviceCommunicationIF, a DH can be tested on different hardware.
By separating the underlying Communication Interface with DeviceCommunicationIF, a device handler (DH) can be tested on different hardware.
The DH has mechanisms to monitor the communication with the physical device which allow for FDIR reaction.
Device Handlers can be created by overriding `DeviceHandlerBase`.
A standard FDIR component for the DH will be created automatically but can be overwritten by the user.
More information on DeviceHandlers can be found in the related [documentation section](doc/README-devicehandlers.md#top).
#### Modes, Health
@ -149,10 +123,6 @@ The health state represents if the component is able to perform its tasks.
This can be used to signal the system to avoid using this component instead of a redundant one.
The on-board FDIR uses the health state for isolation and recovery.
## Example config
A example config can be found in defaultcfg/fsfwconfig.
## Unit Tests
Unit Tests are provided in the unittest folder. Those use the catch2 framework but do not include catch2 itself.

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@ -926,11 +926,6 @@ void DeviceHandlerBase::doTransition(Mode_t modeFrom, Submode_t subModeFrom) {
setMode(getBaseMode(mode));
}
uint32_t DeviceHandlerBase::getTransitionDelayMs(Mode_t modeFrom,
Mode_t modeTo) {
return 0;
}
ReturnValue_t DeviceHandlerBase::getStateOfSwitches(void) {
if(powerSwitcher == nullptr) {
return NO_SWITCH;
@ -1459,3 +1454,11 @@ DeviceCommandId_t DeviceHandlerBase::getPendingCommand() const {
}
return DeviceHandlerIF::NO_COMMAND;
}
void DeviceHandlerBase::setNormalDatapoolEntriesInvalid() {
for(const auto& reply: deviceReplyMap) {
if(reply.second.dataSet != nullptr) {
reply.second.dataSet->setValidity(false, true);
}
}
}

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@ -254,9 +254,10 @@ protected:
*
* @param[out] id the device command id that has been built
* @return
* - @c RETURN_OK to send command after setting #rawPacket and #rawPacketLen.
* - @c NOTHING_TO_SEND when no command is to be sent.
* - Anything else triggers an even with the returnvalue as a parameter.
* - @c RETURN_OK to send command after setting #rawPacket and
* #rawPacketLen.
* - @c NOTHING_TO_SEND when no command is to be sent.
* - Anything else triggers an even with the returnvalue as a parameter.
*/
virtual ReturnValue_t buildNormalDeviceCommand(DeviceCommandId_t * id) = 0;
@ -273,7 +274,8 @@ protected:
* and filling them in doStartUp(), doShutDown() and doTransition() so no
* modes have to be checked here.
*
* #rawPacket and #rawPacketLen must be set by this method to the packet to be sent.
* #rawPacket and #rawPacketLen must be set by this method to the
* packet to be sent.
*
* @param[out] id the device command id built
* @return
@ -284,19 +286,23 @@ protected:
virtual ReturnValue_t buildTransitionDeviceCommand(DeviceCommandId_t * id) = 0;
/**
* @brief Build a device command packet from data supplied by a direct command.
* @brief Build a device command packet from data supplied by a
* direct command.
*
* @details
* #rawPacket and #rawPacketLen should be set by this method to the packet to be sent.
* The existence of the command in the command map and the command size check
* against 0 are done by the base class.
* #rawPacket and #rawPacketLen should be set by this method to the packet
* to be sent. The existence of the command in the command map and the
* command size check against 0 are done by the base class.
*
* @param deviceCommand the command to build, already checked against deviceCommandMap
* @param deviceCommand the command to build, already checked against
* deviceCommandMap
* @param commandData pointer to the data from the direct command
* @param commandDataLen length of commandData
* @return
* - @c RETURN_OK to send command after #rawPacket and #rawPacketLen have been set.
* - Anything else triggers an event with the returnvalue as a parameter
* - @c RETURN_OK to send command after #rawPacket and #rawPacketLen
* have been set.
* - Anything else triggers an event with the
* returnvalue as a parameter
*/
virtual ReturnValue_t buildCommandFromCommand(DeviceCommandId_t deviceCommand,
const uint8_t * commandData, size_t commandDataLen) = 0;
@ -484,7 +490,7 @@ protected:
* @param modeTo
* @return time in ms
*/
virtual uint32_t getTransitionDelayMs(Mode_t modeFrom, Mode_t modeTo);
virtual uint32_t getTransitionDelayMs(Mode_t modeFrom, Mode_t modeTo) = 0;
/**
* Return the switches connected to the device.
@ -681,7 +687,7 @@ protected:
//! The dataset used to access housekeeping data related to the
//! respective device reply. Will point to a dataset held by
//! the child handler (if one is specified)
LocalPoolDataSetBase* dataSet;
LocalPoolDataSetBase* dataSet = nullptr;
//! The command that expects this reply.
DeviceCommandMap::iterator command;
};
@ -743,6 +749,17 @@ protected:
//!< Object which may be the root cause of an identified fault.
static object_id_t defaultFdirParentId;
/**
* @brief Set all datapool variables that are update periodically in
* normal mode invalid
* @details
* The default implementation will set all datasets which have been added
* in #fillCommandAndReplyMap to invalid. It will also set all pool
* variables inside the dataset to invalid. The user can override this
* method optionally.
*/
virtual void setNormalDatapoolEntriesInvalid();
/**
* Helper function to get pending command. This is useful for devices
* like SPI sensors to identify the last sent command.
@ -785,7 +802,6 @@ protected:
*
* The submode is left unchanged.
*
*
* @param newMode
*/
void setMode(Mode_t newMode);
@ -838,8 +854,6 @@ protected:
virtual void doTransition(Mode_t modeFrom, Submode_t subModeFrom);
/**
* Is the combination of mode and submode valid?
*
* @param mode
* @param submode
* @return
@ -850,13 +864,10 @@ protected:
Submode_t submode);
/**
* Get the Rmap action for the current step.
*
* Get the communication action for the current step.
* The step number can be read from #pstStep.
*
* @return The Rmap action to execute in this step
* @return The communication action to execute in this step
*/
virtual CommunicationAction getComAction();
/**
@ -898,8 +909,8 @@ protected:
* It gets space in the #IPCStore, copies data there, then sends a raw reply
* containing the store address.
*
* This method is virtual, as the STR has a different channel to send
* raw replies and overwrites it accordingly.
* This method is virtual, as devices can have different channels to send
* raw replies
*
* @param data data to send
* @param len length of @c data
@ -918,7 +929,7 @@ protected:
void replyRawReplyIfnotWiretapped(const uint8_t *data, size_t len);
/**
* notify child about mode change
* @brief Notify child about mode change.
*/
virtual void modeChanged(void);
@ -950,8 +961,7 @@ protected:
DeviceCommandId_t alternateReplyID = 0);
/**
* get the state of the PCDU switches in the datapool
*
* Get the state of the PCDU switches in the local datapool
* @return
* - @c PowerSwitchIF::SWITCH_ON if all switches specified
* by #switches are on
@ -961,15 +971,6 @@ protected:
*/
ReturnValue_t getStateOfSwitches(void);
/**
* @brief Set all datapool variables that are update periodically in
* normal mode invalid
* @details TODO: Use local pools
* Child classes should provide an implementation which sets all those
* variables invalid which are set periodically during any normal mode.
*/
virtual void setNormalDatapoolEntriesInvalid() = 0;
/**
* build a list of sids and pass it to the #hkSwitcher
*/

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@ -131,7 +131,7 @@ public:
// Standard codes used in interpretDeviceReply
static const ReturnValue_t DEVICE_DID_NOT_EXECUTE = MAKE_RETURN_CODE(0xC0); //the device reported, that it did not execute the command
static const ReturnValue_t DEVICE_REPORTED_ERROR = MAKE_RETURN_CODE(0xC1);
static const ReturnValue_t UNKNOW_DEVICE_REPLY = MAKE_RETURN_CODE(0xC2); //the deviceCommandId reported by scanforReply is unknown
static const ReturnValue_t UNKNOWN_DEVICE_REPLY = MAKE_RETURN_CODE(0xC2); //the deviceCommandId reported by scanforReply is unknown
static const ReturnValue_t DEVICE_REPLY_INVALID = MAKE_RETURN_CODE(0xC3); //syntax etc is correct but still not ok, eg parameters where none are expected
// Standard codes used in buildCommandFromCommand

21
doc/README-config.md Normal file
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@ -0,0 +1,21 @@
## Configuring the FSFW
The FSFW can be configured via the `fsfwconfig` folder. A template folder has
been provided to have a starting point for this. The folder should be added
to the include path.
### Configuring the Event Manager
The number of allowed subscriptions can be modified with the following
parameters:
``` c++
namespace fsfwconfig {
//! Configure the allocated pool sizes for the event manager.
static constexpr size_t FSFW_EVENTMGMR_MATCHTREE_NODES = 240;
static constexpr size_t FSFW_EVENTMGMT_EVENTIDMATCHERS = 120;
static constexpr size_t FSFW_EVENTMGMR_RANGEMATCHERS = 120;
}
```

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doc/README-core.md Normal file
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@ -0,0 +1,50 @@
## FSFW Core Modules
These core modules provide the most important functionalities of the
Flight Software Framework
### Clock
* This is a class of static functions that can be used at anytime
* Leap Seconds must be set if any time conversions from UTC to other times is used
### ObjectManager
* Must be created during program startup
* The component which handles all references. All SystemObjects register at this component.
* Any SystemObject needs to have a unique ObjectId. Those can be managed like objects::framework_objects.
* A reference to an object can be get by calling the following function. T must be the specific Interface you want to call.
A nullptr check of the returning Pointer must be done. This function is based on Run-time type information.
``` c++
template <typename T> T* ObjectManagerIF::get( object_id_t id )
```
* A typical way to create all objects on startup is a handing a static produce function to the ObjectManager on creation.
By calling objectManager->initialize() the produce function will be called and all SystemObjects will be initialized afterwards.
### Event Manager
* Component which allows routing of events
* Other objects can subscribe to specific events, ranges of events or all events of an object.
* Subscriptions can be done during runtime but should be done during initialization
* Amounts of allowed subscriptions can be configured in `FSFWConfig.h`
### Health Table
* A component which holds every health state
* Provides a thread safe way to access all health states without the need of message exchanges
### Stores
* The message based communication can only exchange a few bytes of information inside the message itself. Therefore, additional information can
be exchanged with Stores. With this, only the store address must be exchanged in the message.
* Internally, the FSFW uses an IPC Store to exchange data between processes. For incoming TCs a TC Store is used. For outgoing TM a TM store is used.
* All of them should use the Thread Safe Class storagemanager/PoolManager
### Tasks
There are two different types of tasks:
* The PeriodicTask just executes objects that are of type ExecutableObjectIF in the order of the insertion to the Tasks.
* FixedTimeslotTask executes a list of calls in the order of the given list. This is intended for DeviceHandlers, where polling should be in a defined order. An example can be found in defaultcfg/fsfwconfig/pollingSequence

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@ -0,0 +1 @@
## FSFW DeviceHandlers