...better make it noncopyable to enforce the builder-style use.
In the recent test, I observed strange behaviour when erroneously passing
the CommandDef by value; the command seemed to be registered just fine,
but afterwards, the registry was empty. I must admit I don't understand
this, just from reading the code in CommandDef and Command it should
work just fine to activate a copy of the originally started CommandDef;
anyway, I didn't care to track that issue down, rather make the
CommandDef noncopyable as it should have been right from start.
The point in question is how to manage these definitions in practice,
since we're about to create a huge lot of them eventually. The solution
attempted here is heavily inspired by the boost-test framework
command processing against the session is not yet implemented,
so to allow for unit testing, we magically recognise all commands
starting with "test." and invoke them directly within the Dispatcher.
With this addition, the basic functionality of the dispatcher works now
...since the session loop will be notified on any change via the
interface, adding a command will activate the loop, and the builder
timeout is handled separately via the dirty state. So there is no
need to spin around the loop in idle state.
As a aside, timeout waiting on a condition variable can be intentional
and should thus not be logged as an error automatically. It is up to the
calling context to decide if a timeout constitutes an exceptional situation.
It is always a trade-off performance vs. readability.
Sometimes a single-threaded implementation of self-contained logic
is preferable to a slightly more performant yet obscure implementation
based on our threadpool and scheduler.
Did a full review of state and locking logic, seems airtight now.
- command processing itself is unimplemented, we log a TODO message for now
- likewise, builder is not implemented
- need to add the deadlock safeguard #1054
Due to object scoping we can conclude reliably that the only one
ever to delete the DispacherLoop object will be the the loop thread
from within this object itself, when invoking the termination callback.
Btw, the lock on the inner object was insufficient and will be
replaced by taking the outer lock
It turns out we *do* support the use of anonymous commands
(while it is not clear yet if we really need this feature).
Basically, client code may either create and register a new
instance from another command used as prototype, by invoking
Command::storeDef(ID). Or, alternatively it may just invoke
newInstance() on the command, which creates a new handle
and a valid new implementation (managed by the handle as
smart-ptr), but never stores this implementation into the
CommandRegistry. In that case, client code may use such a
command just fine, as long as it cares to hold onto that
handle; but it is not possible to retrieve this command
instance later by symbolic ID.
In the light of this (possible) usage pattern, it doesn't
make sense to throw when accessing a command-ID. Rather, we
now return a placeholder-Symbol ("_anonymous_")
after reading some related code, I am leaning towards a design
to mirror the way command messages are sent over the UI-Bus.
Unfortunately this pretty much abandons the possibility to
invoke these operations from a client written in C or any
other hand made language binding. Which pretty much confirms
my initial reservation towards such an excessively open
and generic interface system.
...this means to turn Looper into a state machine.
Yet it seems more feasible, since the DispatcherLoop has a nice
checkpoint after each iteration through the while loop, and we'd
keep that whole builder-dirty business completely confined within
the Looper (with a little help of the DispatcherLoop)
Let's see if the state transition logic can actually be implemented
based just on such a checkpoint....?
....if by some weird coincidence, a command dispatched into the session
happens to trigger session shutdown or re-loading, this will cause a deadlock,
since decommissioning of session data structures must wait for the
ProcDispatcher to disable command processing -- and this will obviously
never happen when in a callstack below some command execution!
