spec_exceptionHandling.dox

// put the namespace around the doxygen block so we don't have to give it all the time in the code to get links
namespace ChimeraTK {
/**
\page spec_execptionHandling Technical specification: Exception handling for device runtime errors

<b>DRAFT VERSION, WRITE-UP IN PROGRESS!</b>

\section spec_execptionHandling_intro Introduction

Exceptions are handled by ApplicationCore in a way that the application developer does not need to care much about it.

ChimeraTK::runtime_error exceptions are caught by the framework and are reported to the DeviceModule. The DeviceModule handles this exception and periodically tries to open the device. Communication with the faulty device is frozen or delayed until the device is functional again. In case of several devices only the faulty device is frozen. Faulty devices do not prevent the application from starting, only the parts of the application that depend on the fault device are waiting for the device to come up.

Input variables of ApplicationModules which cannot be read due to a faulty device will set and propagate the DataValidity::faulty flag (see also the \link spec_dataValidityPropagation Technical specification: data validity propagation\endlink).

When the device is functional, it be (re)initialised by using application-defined initialisation handlers and also recover the last known values of its process variables.

\subsection spec_exceptionHandling_intro_terminology Special terminology used in this document

- An read operation might be "skipped". It means, the operation will not take place at all. Instead, the data is marked as DataValidity::faulty. Note: This term is also used, if the a running operation is interrupted by an exception.
- An read operation might be "frozen". This means, the function called will not return until the fault state is resolved and the operation is executed. Freezing always happens before the actual operation is executed and hence will always act on pre-existing fault states only.
- An write operation might be "delayed". This means, the operation will not be executed immediately and the calling thread continues. The operation will be asynchronosuly executed when the fault state is resolved. Note that the VersionNumber specified in the write operation will be retained and also used for the delayed write operation.
- Whenever a write operation or a call to write() is mentioned, destructive writes via writeDestructively() are included. The destructive write optimisation makes no difference for the exception handling.


\section spec_execptionHandling_behaviour A. Behavioural description

- 1. All ChimeraTK::runtime_error exceptions thrown by device register accessors are handled by the framework and are never exposed to user code in ApplicationModules.
  - \anchor a_1_1 1.1 ChimeraTK::logic_error exceptions are left unhandled and will terminate the application. These errors may only occur in the (re-)initialisation phase (up to the point where all devices are opened and initialised) and point to a severe configuration error which is not recoverable. \ref comment_a_1_1 "(*)"
  - \anchor a_1_2 1.2 <b>Exception handling and DataValidity flag propagation is implemented such that it is transparent to a module whether it is directly connected to a device, or whether a fanout or another application module is in between.</b> This is the central requirement from which most other requirements are derived.

- \anchor a_2 2. When an exception has been received by the framework (thrown by a device register accessor):
  - 2.1 The exception status is published as a process variable together with an error message.
    - 2.1.1 The variable \c Devices/\<alias\>/status contains a boolean flag whether the device is in an error state
    - 2.1.2 The variable \c Devices/\<alias\>/message contains an error message, if the device is in an error state, or an empty string otherwise.
  - \anchor a_2_2 2.2 Read operations will propagate the DataValidity::faulty flag to the owning module / fan out (without changing the actual value):
    - 2.2.1 The normal module algorithm code will be continued, to allow this flag to propagate to the outputs in the same way as if it had been received through the process variable itself (cf. \ref a_1_2 "1.2").
    - 2.2.2 The DataValidity::faulty flag resulting from the fault state is propagated once, even if the variable had the a DataValidity::faulty flag already set previously for another reason.
    - \anchor a_2_2_3 2.2.3 Read operations without AccessMode::wait_for_new_data are skipped until the device is fully recovered again (cf. \ref a_3_1 "3.1").
    - \anchor a_2_2_4 2.2.4 Read operations with AccessMode::wait_for_new_data will be skipped once for each accessor to propagate the DataValidity::faulty flag (which counts as new data, i.e. readNonBlocking() will return true). In the following:
      - non-blocking read operations (readNonBlocking() and readLatest()) are skipped and return false, until new data has arrived from the device, and
      - blocking read operations (read()) will freeze until new data has arrived from the device.
      - Note: The device may start sending data already before the recovery procedure (cf. \ref a_3_1 "3.1") is complete. If this is not acceptable, a device specific handshake mechanism has to be implemented in the application to control when the device is allowed to send updates again. \ref comment_a_2_2_4 "(*)"
    - \anchor a_2_2_5 2.2.5 If the fault state had been resolved in between one read operation (regardless of the type) and a second blocking read operation, and the device had become faulty again before the second operation is executed, it is not defined whether the second operation will frozen or skipped. The second operation might in this case behave either like it is a new exception or like the same fault state would still prevail. \ref comment_a_2_2_5 "(*)"
  - \anchor a_2_3 2.3 Write operations will be delayed until the device is fully recovered again (cf. \ref a_3_1 "3.1"). In case of a fault state (new or persisting), the actual write operation will take place asynchronously when the device is recovering. The same mechanism as used for \ref a_3_1_2 "3.1.2" is used here, hence the order of write operations is guaranteed across accessors, but only the latest written value of each accessor prevails. \ref comment_a_2_3 "(*)"
    - 2.3.1 The return value of write() indicates whether data was lost in the transfer. If the write has to be delayed due to an exception, the return value will be true, if a previously delayed and not-yet written value is discarded in the process, false otherwise.
    - 2.3.2 When the delayed value is finally written to the device during the recovery procedure, it is guaranteed that no data loss happens (writes with data loss will be retried).
    - 2.3.3 It is guaranteed that the write takes place before the device is considered fully recovered again and other transfers are allowed (cf. \ref a_3_1 "3.1").
  - \anchor a_2_4 2.4 In case of exceptions, there is no guaranteed realtime behaviour, not even for "non-blocking" transfers. \ref comment_a_2_4 "(*)"

- 3. The framework tries to resolve an exception state by periodically re-opening the faulty device.
  - \anchor a_3_1 3.1 After successfully re-opening the device, a recovery procedure is executed before allowing any read/write operations from the AppliactionModules and FanOuts again. This recovery procedure involves:
    - 3.1.1 the execution of so-called initialisation handlers (see \ref a_3_2 "3.2"), and
    - \anchor a_3_1_2 3.1.2 restoring all registers that have been written since the start of the application with their latest values. The register values are restored in the same order they were written. \ref comment_a_3_1_2 "(*)"
    - \anchor a_3_1_3 3.1.3 Finally, \c Devices/\<alias\>/deviceBecameFunctional is written to inform any module subscribing this variable about the finished recovery. \ref comment_a_3_1_3 "(*)"
  - \anchor a_3_2 3.2 Any number of initialisation handlers can be added to the DeviceModule in the user code. Initialisation handlers are callback functions which will be executed when a device is opened for the first time and after a device recovers from an exception, before any process variables are written. See DeviceModule::addInitialisationHandler().

- 4. The behaviour at application start (when all devices are still closed at first) is similar to the case of a later received exception. The only differences are mentioned in \ref a_4_2 "4.2".
  - 4.1 Even if some devices are initially in a persisting error state, the part of the application which does not interact with the faulty devices starts and works normally.
  - \anchor a_4_2 4.2 Initial values are correctly propagated after a device is opened. See the \link spec_initialValuePropagation Technical specification: propagation of initial values\endlink. Especially, all read operations (even readNonBlocking/readLatest) will be frozen until an initial value has been received. \ref comment_a_4_2 "(*)"

- \anchor a_5 5. Any ApplicationModule can explicitly report a problem with the device by calling DeviceModule::reportException(). This allows the reinitialisation of a device e.g. after a reboot of the device which didn't result in a exception (e.g. because it was too quick to be noticed, or rebooting the device takes place without interrupting the communication).


\subsection spec_execptionHandling_behaviour_comments (*) Comments

- \anchor comment_a_1_1 \ref a_1_1 "1.1" In future, maybe logic_errors are also handled, so configuration errors can nicely be presented to the control system. This may be important especially since logic_errors may depend also on the configuration of external components (devices). If e.g. a device is changed (e.g. device is another control system application which has been modified), logic_errors may be thrown in the recovery phase, despite the device had been successfully initialsed previously.

- \anchor comment_a_2_2_4 \ref a_2_2_4 "2.2.4" Preventing the device to send data before the recovery is complete is not trivial in the general case for asynchronous transfers (i.e. wait_for_new_data). Race conditions might occur if the transport layer does not guarantee the order of packets (e.g. UDP), in which case unsubscribing a variable might not guarantee that no more data arrives which has been sent before unsubscribing. Hence it was decided not to specify a mechanism which would guarantee that no asychronous data transfers take place before the recovery has completed.

- \anchor comment_a_2_2_5 \ref a_2_2_5 "2.2.5" Not defining the behaviour here avoids a conflict with 1.2 without requiring a complicated implementation which does not freeze in this case. Implementing this would not present any gain for the application. If there are many exceptions on the same device in a short period of time, the number of faulty data updates seen by the application modules will always depend on the speed the module is attempting to read data (unless we require every exception to be visible to every module, but this will have complex effects, too). It might break consistency of the number of updates sent through different paths in an application, but applications should anyway not rely on that and use a DataConsistencyGroup to synchronise instead. Hence, the implementation will freeze always if a blocking read sees an exception after the last read of the same accessor had seen an exception (the same or a different one) as well.

- \anchor comment_a_2_3 \anchor comment_a_3_1_3 \ref a_2_3 "2.3" / \ref a_3_1_3 "3.1.3" If timing is important for write operations (e.g. must not write a sequence of registers too fast), or if multiple values need to be written to the same register in sequence, the application cannot fully rely on the framework's recovery procedure. The framework hence provides the process variable \c Devices/\<alias\>/deviceBecameFunctional for each device, which will be written each time the recovery procedure is completed (cf. \ref a_3_1_3 "3.1.3"). ApplicationModules which implement such timed sequence need to receive this variable and restart the entire sequence after the recovery.

- \anchor comment_a_2_4 \ref a_2_4 "2.4" Even read without wait_for_new_data and write operations are not truely non-blocking, since they are still synchronous. The "non-blocking" guarantee only means that the operation does not block until new data has arrived, and that it is not frozen until the device is recovered. For the duration of the recovery procedure and of course for timeout periods these operations may still block. readNonBlocking() and readLatest() with wait_for_new_data could in theory be truely lock-free and wait-free, but the synchronisation mechanism in case of exceptions are not implemented as such. In case of exceptions, the application usually anway does not behave normally any more. If needed, this limitation could be lifted with a more complicated implementation in the future.

- \anchor comment_a_3_1_2 \ref a_3_1_2 "3.1.2" For some applications, the order of writes may be important, e.g. if firmware expects this. Please note that the VersionNumber is insufficient as a sorting criteria, since many writes may have been done with the same VersionNumber (in an ApplicationModule, the VersionNumber used for the writes is determined by the largest VersionNumber of the inputs).

- \anchor comment_a_4_2 \ref a_4_2 "4.2" DataValidity::faulty is initially set by default, so there is no need to propagate this flag initially. To prevent race conditions and undefined behaviour (especially in automated tests), it even needs to be made sure that the flag is not propagated unnecessarily. The behaviour of non-blocking reads presents a slight asymmetry between the initial device opening and a later recovery. This will in particular be visible when restarting a server while a device is offline. If a module only uses readLatest()/readNonBlocking() (= read() for poll-type inputs) for the offline device, the module was still running before the server restart using the last known values for the dysfunctional registers (and flagging all outputs as faulty). After the restart, the module has to wait for the initial value and hence will not run until the device becomes functional again. To make this behaviour symmetric, one would need to persist the values of device inputs. Since this only affects a corner case in which likely no usable output is produced anyway, this slight inconsistency is considered acceptable.


\section spec_execptionHandling_high_level_implmentation B. Implementation

A so-called ExceptionHandlingDecorator is placed around all device register accessors (used in ApplicationModules and FanOuts). It is responsible for catching the exceptions and implementing most of the behaviour described in \ref a_2 "A.2", and its implementation is described in \ref spec_execptionHandling_high_level_implmentation_decorator "B.2". It has to work closely with the DeviceModule and there is a complex synchronisation and locking scheme, which is described in \ref spec_execptionHandling_high_level_implmentation_interface "B.1". The sequence executed in the DeviceModule is described in \ref spec_execptionHandling_high_level_implmentation_deviceModule "B.3".


\subsection spec_execptionHandling_high_level_implmentation_interface B.1 Internal interface between ExceptionHandlingDecorator and DeviceModule

Note: This section defines the internal interface on a low level. Helper functions, like getters and setters, are intenionally not mentioned here, since those are (in this context) unimportant details which can be chosen at will to structure the code conveniently. The entire interface between the ExceptionHandlingDecorator and the DeviceModule should be protected and the two classes should be friends, to prevent interference with the interface from other entities. Only DeviceModule::reportException() is public, see \ref a_5 "A.5".

- 1.1 The boolean flag DeviceModule::deviceHasError
  - 1.1.1 is used by the ExceptionHandlingDecorator to detect prevailing error conditions, to know when transfers have to be skipped, frozen or delayed (cf. \ref b_2_3 "2.3" and \ref b_2_4 "2.4").
  - 1.1.2 The access is protected by the DeviceModule::errorMutex:
    - shared lock allows to read
    - unique lock allows to read and write

- \anchor b_1_2 1.2 The atomic DeviceModule::transferCounter \ref comment_b_1_2 "(*)"
  - 1.2.1 tracks the number of on-going (synchronous) transfers, and
  - 1.2.2 is used by the DeviceModule to wait until they are all terminated (\ref b_3_3_14 "3.3.14").

- \anchor b_1_3 1.3 The DeviceModule::recoveryHelpers list elements
  - 1.3.1 are used to delay write operations and to restore the last-written values during recovery.
  - \anchor b_1_3_2 1.3.2 are protected by the DeviceModule::recoveryMutex:
    - shared lock allows to update the application buffer of RecoveryHelper::accessor and to update the other members of the RecoveryHelper structure \ref comment_b_1_3_2 "(*)"
    - unique lock allows to call RecoveryHelper::accessor.write() and to read/write the other members of the RecoveryHelper structure

- 1.4 The cppext::future_queue DeviceModule::errorQueue
  - 1.4.1 is used by the ExceptionHandlingDecorator to inform the DeviceModule about new exceptions.
  
- 1.5 The following mutexes govern critical sections (besides variable access listed above):
  - \anchor b_1_5_1 1.5.1 DeviceModule::errorMutex protects \ref comment_b_1_5_1 "(*)"
    - the (positive) decision to start a transfer followed by incrementing the DeviceModule::transferCounter in \ref b_2_3_1 "2.3.1" to \ref b_2_3_3 "2.3.3", against
    - setting DeviceModule::deviceHasError flag in \ref b_2_6_1 "2.6.1".

  - \anchor b_1_5_2 1.5.2 DeviceModule::recoveryMutex protects \ref comment_b_1_5_2 "(*)"
    - writing the DeviceModule::recoveryHelpers to the device and clearing the DeviceModule::deviceHasError flag in \ref b_3_3_6 "3.3.6" to \ref b_3_3_8 "3.3.8", against
    - updating the DeviceModule::recoveryHelpers in \ref b_2_2 "2.2".

  - \anchor b_1_5_3 1.5.3 DeviceModule::initialValueMutex protects \ref comment_b_1_5_3 "(*)"
    - the start of a read operation in \ref b_2_4_4 "2.4.4", against
    - the setup phase of a device until it has been opened and recovered for the very first time in \ref b_3_1 "3.1" to \ref b_3_3_9 "3.3.9".

- 1.6 DeviceModule::listOfReadRegisters resp. DeviceModule::listOfWriteRegisters
  - 1.6.1 are used to check that all used registers are existing and have the right direction after (re-)opening the device.
  - 1.6.2 No lock for accessing is required, since the lists are filled in the constructors of the ExceptionHandlingDecorator and in the following only used by the DeviceModule thread.


\subsubsection spec_execptionHandling_high_level_implmentation_interface_comments (*) Comments

- \anchor comment_b_1_2 \ref b_1_2 "1.2" Reason for not using an (exclusive) lock: Incrementing and decrementing the counter is done in the ExceptionHandlingDecorator for each operation, even if there is no exception or error state. Concurrent operations must not exclude each other, to allow lockfree operation in the no-exception case (if the backend supports it) and to avoid priority inversion, if different application threads have different priorities.

- \anchor comment_b_1_3_2 \ref b_1_3_2 "1.3.2" A shared lock (in contrast to an exclusive lock) is used for the same reasons as in \ref b_1_2 "1.2".

- \anchor comment_b_1_5_1 \ref b_1_5_1 "1.5.1" This prevents a race condition in \ref b_3_3_14 "3.3.14". If a (synchronous) transfer might be started after DeviceModule::deviceHasError has been set, the barrier for new transfers in \ref b_3_3_14 "3.3.14" would not be effective and the transfer might be even executed only after the device has been re-openend (\ref b_3_3_1 "3.3.1") but before the recovery is complete.

- \anchor comment_b_1_5_2 \ref b_1_5_2 "1.5.2" This prevents data loss due to a race condition. If the ExceptionHandlingDecorator would update the corresponding DeviceModule::RecoveryHelpers list entry only after it has been written to the device in \ref b_3_3_6 "3.3.6", but the ExceptionHandlingDecorator would decide not to execute the write operation (\ref b_2_3 "2.3") because the DeviceModule thread is still before \ref b_3_3_8 "3.3.8", the data would not be written to the device at all.

- \anchor comment_b_1_5_3 \ref b_1_5_3 "1.5.3" This implements freezing reads until the initial value can be read, cf. \ref a_4_2 "A.4.2".


\subsection spec_execptionHandling_high_level_implmentation_decorator B.2 ExceptionHandlingDecorator

- \anchor b_2_1 2.1 A second, undecorated copy of each writeable device register accessor \ref comment_b_2_1 "(*)", the so-called recovery accessor, is stored in the DeviceModule::recoveryHelpers. These recoveryHelpers are used to set the initial values of registers when the device is opened for the first time and to recover the last written values during the recovery procedure.
  - \anchor b_2_1_1 2.1.1 The DeviceModule::recoveryHelpers is a list of RecoveryHelper objects, which each contain:
    - RecoveryHelper::accessor, the recovery accessor itself,
    - RecoveryHelper::versionNumber, the VersionNumber of the (potentially unwritten) data stored in the value buffer of the accessor,
    - RecoveryHelper::writeOrder, an ordering parameter which determines the order of write opereations during recovery.
    - RecoveryHelper::wasWritten, a flag which indicates whether the data in the value buffer of the RecoveryHelper::accessor has already been written to the device. \ref comment_b_2_1_1 "(*)"
  - \anchor b_2_1_2 2.1.2 Ordering can be done per device \ref comment_b_2_1_2 "(*)", hence each DeviceModule has one 64-bit atomic counter DeviceModule::writeCounter which is incremented for each write operation and the value is stored in RecoveryHelper::writeOrder.
  - 2.1.3 The RecoveryHelper objects may be accessed only under a lock, see \ref b_1_3 "1.3".
  
- \anchor b_2_2 2.2 In doPreWrite() the RecoveryHelper is updated while holding a shared lock on DeviceModule::recoveryMutex:
  - \anchor b_2_2_1 2.2.1 These steps needs to be done unconditionally at the very beginning of doPreWrite(), before \ref b_2_3 "2.3" and before delegating to preWrite(). \ref comment_b_2_2_1 "(*)"
  - 2.2.2 If the RecoveryHelper::wasWritten flag was previously not set, the return value of doWriteTransfer() must be forced to true (data lost).
  - 2.2.3 Update the value buffer of the RecoveryHelper::accessor, update the RecoveryHelper::versionNumber, set the RecoveryHelper::writeOrder to the DeviceModule::writeCounter after (atomically) incrementing it, and clear the RecoveryHelper::wasWritten flag.
  - \anchor b_2_2_4 2.2.4 The check whether to skip the transfer (cf. \ref b_2_3 "2.3") has to be done without releasing the lock between the update of the RecoveryHelper and the check. \ref comment_b_2_2_4 "(*)"

- \anchor b_2_3 2.3 In doPreRead()/doPreWrite(), it must be decided whether to execute xxxTransferYyy(). This part requires a shared lock on the DeviceModule::errorMutex.
  - \anchor b_2_3_1 2.3.1 xxxTransferYyy() is <i>not</i> executed, if DeviceModule::deviceHasError == true and either:
    - it is a write transfer (cf. \ref a_2_3 "A.2.3"), or
    - it is a read transfer and AccessMode::wait_for_new_data is not set (cf. \ref a_2_2_3 "A.2.2.3"), or
    - it is a read transfer and AccessMode::wait_for_new_data is set and ExceptionHandlingDecorator::previousReadFailed == false (cf. \ref a_2_2_4 "A.2.2.4", \ref b_2_5_2 "2.5.2" and \ref b_2_6_3_1 "2.6.3.1").
    Otherwise xxxTransferYyy() is executed (potentially after it is frozen, see \ref b_2_4 "2.4").
  - 2.3.2 If xxxTransferYyy() is not executed, none of the pre/transfer/post functions must be delegated to the target accessor.
  - \anchor b_2_3_3 2.3.3 If xxxTransferYyy() is executed, and it is <i>not</i> a read transfer with AccessMode::wait_for_new_data set, the DeviceModule::transferCounter must be incremented.

- \anchor b_2_4 2.4 In doPreRead() certain read operations are frozen (only \ref a_4_2 "A.4.2";  \ref a_2_2_4 "A.2.2.4" does not require an implementation here \ref comment_b_2_4 "(*)"):
  - 2.4.1 The shared lock on the DeviceModule::errorMutex acquired in \ref b_2_3 "2.3" is still kept.
  - 2.4.2 Decide, whether freezing is done (don't freeze yet). Freezing is done if no initial value has been read yet (getCurretVersion() == {nullptr}) and DeviceModule::deviceHasError == true.
  - 2.4.3 Release the DeviceModule::errorMutex.
  - \anchor b_2_4_4 2.4.4 If the read should be frozen, acquire a shared lock on the DeviceModule::initialValueMutex. \ref comment_b_2_4_4 "(*)"

- 2.5 In doPostRead()/doPostWrite():
  - 2.5.1 Delegate to postRead() / postWrite() (see \ref b_2_6 "2.6")
  - \anchor b_2_5_2 2.5.2 If there was no exception, set ExceptionHandlingDecorator::previousReadFailed = false (cf. \ref b_2_3_1 "2.3.1" and \ref b_2_6_3_1 "2.6.3.1").
  - \anchor b_2_5_3 2.5.3 In doPostWrite() the RecoveryHelper::wasWritten flag is set (while holding a shared lock on DeviceModule::recoveryMutex) if the write was successful (no exception thrown; data lost flag does not matter here). \ref comment_b_2_5_3 "(*)"
  - \anchor b_2_5_4 2.5.4 If the DeviceModule::transferCounter was incremented in \ref b_2_3_3 "2.3.3", decrement it. \ref comment_b_2_5_4 "(*)"
  - \anchor b_2_5_5 2.5.5 In doPostRead(), if no exception was thrown, end overriding the DataValidity returned by the accessor (cf. \ref b_2_6_2 "2.6.2").

- \anchor b_2_6 2.6 In doPostRead()/doPostWrite(), any runtime_error exception thrown by the delegated postRead()/postWrite() is caught \ref comment_b_2_6 "(*)". The following actions are executed in case of an exception:
  - \anchor b_2_6_1 2.6.1 The error is reported to the DeviceModule via DeviceModule::reportException() (cf. \ref spec_execptionHandling_high_level_implmentation_reportException "B.4"). This automatically sets DeviceModule::deviceHasError to true. From this point on, no new transfers will be started. \ref comment_b_2_6_1 "(*)"
  - \anchor b_2_6_2 2.6.2 For readable accessors: the DataValidity returned by the accessor is overridden to faulty until next successful read operation (cf. \ref b_2_5_5 "2.5.5").
    - 2.6.2.1 The code instantiating the decorator (Application::createDeviceVariable()) has to make sure that the ExceptionHandlingDecorator is "inside" the MetaDataPropagatingRegisterDecorator, so the overriden DataValidity flag in case of an exception is properly propagated to the owning module/fan out.
  - 2.6.3 Action depending on the calling operation:
    - \anchor b_2_6_3_1 2.6.3.1 All read operations: The ExceptionHandlingDecorator remembers that it is in an exception state by setting ExceptionHandlingDecorator::previousReadFailed = true (cf. \ref b_2_3_1 "2.3.1" and \ref b_2_5_2 "2.5.2")
    - \anchor b_2_6_3_2 2.6.3.2 read (push-type inputs): return immediately \ref comment_b_2_6_3_1 "(*)"
    - 2.6.3.3 readNonBlocking / readLatest / read (poll-type inputs): Just return (true in readLatest() by definition in poll type). The calling module thread will continue and propagate the DataValidity::faulty flag (cf. \ref b_2_6_2 "2.6.2").
    - 2.6.3.4 write: Write will be later executed by the DeviceModule (see \ref b_2_1 "2.1"), hence just return.
    
- 2.7 In the constructor of the decorator, put the name of the register to DeviceModule::listOfReadRegisters resp. DeviceModule::listOfWriteRegisters depending on the direction the accessor is used.

\subsubsection spec_execptionHandling_high_level_implmentation_decorator_comments (*) Comments

- \anchor comment_b_2_1 \ref b_2_1 "2.1" Possible future change: Output accessors can have the option not to have a RecoveryHelper. This is needed for instance for "trigger registers" which start an operation on the hardware. Also void registers don't have a RecoveryHelper (once the void data type is supported by ChimeraTK).

- \anchor comment_b_2_1_1 \ref b_2_1_1 "2.1.1" The written flag cannot be replaced by comparing RecoveryHelper::accessor.getCurrentVersion() and RecoveryHelper::versionNumber, because normal writes (without exceptions) would not update the version number of the RecoveryHelper::accessor. The written flag could also be made atomic to avoid acquiring the shared lock in postWrite(), but since the shared lock will never block there (if acquired before counting down the DeviceModule::transferCounter) is probably no benifit in using an atomic here.

- \anchor comment_b_2_1_2 \ref b_2_1_2 "2.1.2" The ordering guarantee cannot work across DeviceModules anyway. Different devices may go offline and recover at different times. Even in case of two DeviceModules which actually refer to the same hardware device there is no synchronisation mechanism which ensures the recovering procedure is done in a defined order.

- \anchor comment_b_2_2_1 \ref b_2_2_1 "2.2.1" Updating the recoveryHelper first ensures that no data is lost, even if the write operation attempt is concurrent with a recovery. See \ref b_1_5_2 "1.5.2".

- \anchor comment_b_2_2_4 \ref b_2_2_4 "2.2.4" Extending the duration of the lock until the decision whether to skip the transfer will prevent unncessary duplicate writes, which otherwise could occur if the DeviceModule went through the whole critical section \ref b_3_3_5 "3.3.5" to \ref b_3_3_10 "3.3.10" in between.

- \anchor comment_b_2_4 \ref b_2_4 "2.4" In A.2.2.4 it was stated that also in case AccessMode::wait_for_new_data is set blocking read transfers are frozen on the second operation. Nothing is to be implemented for this case, the freezing simply relies on having an empty queue in the accessor. Once the device sends data again, the operation is intrinsically unfrozen.

- \anchor comment_b_2_4_4 \ref b_2_4_4 "2.4.4" The transferCounter is already incremeted at this point. It is acceptable to freeze anyway in this case by waiting on the initialValueMutex, because the DeviceModule release the mutex after the first successful recovery and never obtains it again, and this happens before it waits for the transferCounter to become 0 in \ref b_3_3_14 "3.3.14".

- \anchor comment_b_2_5_3 \ref b_2_5_3 "2.5.3" The RecoveryHelper::wasWritten flag is used to report loss of data. If the loss of data is already reported directly, it should not later be reported again. Hence the written flag is set even if there was a loss of data in this context. Setting the flag is ideally done before decrementing the DeviceModule::transferCounter in \ref b_2_5_4 "2.5.4", because this eliminates the possibility that acquiring the shared lock on the DeviceModule::recoveryMutex could block (exclusive lock is only acquired during recovery, which cannot start before DeviceModule::transferCounter == 0)

- \anchor comment_b_2_5_4 \ref b_2_5_4 "2.5.4" The state of DeviceModule::deviceHasError does not matter here. The counter always MUST be decreased after a transfer (if it has been incremented in the corresponding preXxx()), whether the transfer failed or not.

- \anchor comment_b_2_6 \ref b_2_6 "2.6" Remember: exceptions from other phases are redirected to the post phase by the TransferElement base class.

- \anchor comment_b_2_6_1 \ref b_2_6_1 "2.6.1" No transfers will be started in any of the accessors of the device, including this one. This is important to avoid the race condition described in the comment to \ref b_1_5_1 "1.5.1"

- \anchor comment_b_2_6_3_1 \ref b_2_6_3_2 "2.6.3.2" The freezing is done in doPreRead(), see \ref b_2_4 "2.4".


\subsection spec_execptionHandling_high_level_implmentation_deviceModule B.3 DeviceModule

- \anchor b_3_1 3.1 The application always starts with all devices as closed. For each device, the initial value for \c Devices/\<alias\>/status is set to 1 and the initial value for \c Devices/\<alias\>/message is set to an error that the device has not been opened yet (the message will be overwritten with the real error message if the first attempt to open fails, see \ref b_3_3_1 "3.3.1").

- \anchor b_3_2 3.2 The DeviceModule locks the DeviceModule::initialValueMutex (cf. \ref b_2_4 "2.4"). This happens before launching any module and fan out threads.

- 3.3 In the DeviceModule thread, the following procedure is executed (in a loop until termination):

  - \anchor b_3_3_1 3.3.1 The DeviceModule tries to open the device until it succeeds and Device::isFunctional() returns true.
    - 3.3.1.1 If the very first attempt to open the device after the application start fails, the error message of the exception is used to overwrite the content of \c Devices/\<alias\>/message. Otherwise error messages of exceptions thrown by Device::open() are not visible.
  - \anchor b_3_3_2 3.3.2 The queue of reported exceptions is cleared. \ref comment_b_3_3_2 "(*)"

  - 3.3.3 Check that all registers on DeviceModule::listOfReadRegisters are isReadable() and all registers on DeviceModule::listOfWriteRegisters are isWriteable().
    - 3.3.3.1 This involves obtaining an accessor for the register first, which is discarded after the check.
    - 3.3.3.2 If there is an exception, update \c Devices/\<alias\>/message with the error message and go back to \ref b_3_3_1 "3.3.1".
    - 3.3.3.3 If one of the accessors does not meet this condition, throw a ChimeraTK::logic_error.

  - 3.3.4 The device is initialised by iterating DeviceModule::initialisationHandlers list and executing the functors.
    - 3.3.4.1 If there is an exception, update \c Devices/\<alias\>/message with the error message and go back to \ref b_3_3_1 "3.3.1".

  - \anchor b_3_3_5 3.3.5 Obtain unique lock on DeviceModule::recoveryMutex.

  - \anchor b_3_3_6 3.3.6 Call write() on all valid RecoveryHelper::accessor, in the ascending order of the RecoveryHelper::writeOrder.
    - 3.3.6.1 A RecoveryHelper::accessor is considered "valid", if it has already received a value, i.e. RecoveryHelper::versionNumber != {nullptr}
    - 3.3.6.2 If there is an exception, update \c Devices/\<alias\>/message with the error message, release the lock and go back to \ref b_3_3_1 "3.3.1".

  - 3.3.7 \c Devices/\<alias\>/status is set to 0 and \c Devices/\<alias\>/message is set to an empty string. \c Devices/\<alias\>/deviceBecameFunctional is written.
  - \anchor b_3_3_8 3.3.8 Clear the DeviceModule::deviceHasError flag to allow the ExceptionHandlingDecorator to execute read/write operations again (cf. \ref b_3_3_12 "3.3.12")
  - \anchor b_3_3_9 3.3.9 Release the DeviceModule::initialValueMutex, if this point is passed for the very first time (was obtained in \ref b_3_2 "3.2", cf. \ref b_2_4_4 "2.4.4"). 
  - \anchor b_3_3_10 3.3.10 Release lock on DeviceModule::recoveryMutex (was obtained in \ref b_3_3_5 "3.3.5").
  - 3.3.11 The DeviceModuleThread waits for the next reported exception.
  - \anchor b_3_3_12 3.3.12 An exception is received. The call to reportException (cf. \ref spec_execptionHandling_high_level_implmentation_reportException "B.4") in the other thread has already set deviceHasError to true \ref comment_b_3_3_12 "(*)". From this point on, no new transfers will be started.
  - 3.3.13 \c Devices/\<alias\>/status is set to 1 and \c Devices/\<alias\>/message is set to the first received exception message.
  - \anchor b_3_3_14 3.3.14 The device module waits until all running read and write operations of ExceptionHandlingDecorators have ended (wait until DeviceModule::activeTransfers == 0). \ref comment_b_3_3_14 "(*)"
  - 3.3.15 The thread goes back to \ref b_3_3_1 "3.3.1" and tries to re-open the device.

\subsubsection spec_execptionHandling_high_level_implmentation_deviceModule_comments (*) Comments

- \anchor comment_b_3_3_2 \ref b_3_3_2 "3.3.2" The exact place when this is done does not matter, as long as it is done after \ref b_3_3_14 "3.3.14" (no ongoing synchronous transfers) and before \ref b_3_3_8 "3.3.8" (resetting deiveHasError). As soon as deviceHasError is cleared new exceptions can be reported, which would be lost if the list was cleared afterwards. Moving it as early as possible after the device has been reopenend has the (slight) advantage, that exceptions which might be reported by asynchronous transfers during the recovery are not discarded, even if the recovery itself does't catch them for some reason. Since exceptions reported by asynchronous transfers are subject to race conditions with the recovery procedure, there cannot be strict guarantees about the behaviour. The optimal place where to reset the queue (to minimise unnecessary recoveries while minimising the probability of rejecting true errors which then need to be found instead later by other transfers) might need to be found in real-life experiments later.

- \anchor comment_b_3_3_12 \ref b_3_3_12 "3.3.12" Setting the DeviceModule::deviceHasError flag has to be done in the application thread which has caught the exception. If you just send a message and let the device module do both setting and clearing of the flag you can have a race condition: A blocking read would inform the DeviceModule about an exception and continue. The next call to the blocking read is supposed to freeze, but pre-read might not detect this because the device module thread has not woken up yet to set the error flag.

- \anchor comment_b_3_3_14 \ref b_3_3_14 "3.3.14" The backend has to take care that all operations, also the blocking/asynchronous reads with "waitForNewData", terminate when an exception is thrown, so recovery can take place (see DeviceAccess TransferElement specification).


\subsection spec_execptionHandling_high_level_implmentation_reportException B.4 DeviceModule::reportException()

- 4.1 Acquire unique lock on DeviceModule::errorMutex.
- 4.2 Just return, if DeviceModule::deviceHasError is already true.
- 4.3 Set DeviceModule::deviceHasError to true.
- 4.4 Write exception message to DeviceModule::errorQueue.


\section spec_execptionHandling_known_issues C. Known issues

TODO

*/

} // end of namespace ChimeraTK