We found out that it's best to run it single threaded
within the session loop thread. This does not mean the Builder
itself is necessarily single threaded, but the Builder's top level
will block any other session operation, and this is a good thing.
For this reason it makes more sense to have the Builder integrated
as a component into the session subsystem.
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!
After some consideration, it became clear that this service implementation
is closely tied to the DispatcherLoop -- which will consequently be
responsible to run and expose this service implementation
need to keep state variables on both levels,
since the session manager (lifecycle) "opens" the session
for external access by starting the dispatcher; it may well happen
thus that the session starts up, while the *session subsystem*
is not(yet) started
mark TODOs in code to make that happen.
Actually, it is not hard to do so, it just requires to combine
all the existing building blocks. When this is done, we can define
the "Session" subsystem as prerequisite for "GUI" in main.cpp
Unless I've made some (copy-n-paste) mistake with defining the facades,
this should be sufficient to pull up "the Session" and automatically
let the Gui-Plugin connect against the SessionCommandService
up to now this happened from the GuiRunner, which was a rather bad idea
- it can throw and thus interfer with the startup process
- the GuiNotification can not sensibly be *implemented* just backed
by the GuiRunner. While CoreService offers access to the necessary
implementation facilities to do so
so the true reason is an inner contradiction in the design
- I want it to be completely self similar
- but the connection to CoreService does not conform
- and I do not want to hard code CoreService into the Nexus classdefinition
So we treat CoreService as uplink für Nexus and Nexus as uplink for CoreService,
with the obvious consequences that we're f**ed at init and shutdown.
And since I want to retain the overall design, I resort to implement
a short circuit detector, which suppresses circular deregistration calls
Decision was made to use the CoreService as PImpl to organise
all those technical aspects of running the backbone. Thus,
the Nexus (UI-Bus hub) becomes part of CoreService
...problem is, I actually don't know much about what kinds of markers
we'll get, and how we handle them. Thus introducing a marker kind
is just a wild guess, in order to get *any* tangible attribute
this is a tricky problem and a tough decision.
After quite some pondering I choose to enforce mandatory fields
through the ctor, and not to allow myself cheating my way around it
it occurred to me that effectively we abandoned the use of
a business facade and proxy model in the UI. The connection
becomes entirely message based now.
To put that into context, the originally intended architecture
never came to life. The UI development stalled before this could
happen; possibly it was also hampered by the "impedance mismatch"
between our intentions in the core and such a classical, model centric
architecture. Joel several times complained that he felt blocked; but
I did not really understand this issue. Only recently, when I came to
adapting the timeline display to GTK-3, I realised the model centric
approach can not possibly work with such an open model as intended
in our case. It would lead to endless cascades of introspection.
these are just empty class files, but writing a basic description
for each made me flesh out a lot of organisational aspects of what
I am about to build now
...it seemed first that we'd might run into a very fundamental problem;
but after some consideration it turns out the interspersed display manager
and the decoupling between model/presenter and widget happens to mitigate
this problem as well.
the content of the "GuiTimelineWidgetStructure" tiddler is
actually related to architecture questions related to custom widgets
in general, plus working notes regarding an investigation of the
Gtk::Layout widget.
bottom line
- seems we need to do that manually
- must wait until in the on_draw() callback
- use Container::foreach() to visit all child widgets
- Layout::set_size()
- define tasks to be addressed during investigation
- read documentation, identify problematic aspects
- prepare a child widget class to be placed on the canvas
actually this is a pragmatic extension for some special use cases,
and in general rather discurraged, since it contradicts the
established diff semantics. Yet with some precaution, it should
be possible to transport information via an intermediary ETD
Map -> ETD -> Map
...this is the first attempt to integrate the Diff-Framework into (mock) UI code.
Right now there is a conceptual problem with the representation of attributes;
I tend to reject idea of binding to an "attribute map"
the generic typing to DiffMutatble does not make much sense,
since the desired implementation within gui::ctrl::Nexus
is bound to work on Tangibles only, since that is what
the UI-Bus stores in the routing table
at first, this seemed like a good idea, but it caused already
numerous quirks and headache all over the place. And now, with
the intent to switch to the TreeMutator based implementation,
it would be damn hard to retain these features, if at all
possible.
Thus let's ditch those in time and forget about it!
this is a subtle change in the semantics of the diff language,
actually IMHO a change towards the better. It was prompted by the
desire to integrate diff application onto GenNode-trees into the
implementation framework based on TreeMutator, and do away with
the dedicated implementation.
Now it is a matter of the *selector* to decide if a given layer
is responsible for "attributes". If so, then *all* elements within
this layer count as "attribute" and an after(Ref::ATTRIBS) verb
will fast forward behind *the end of this layer*
Note that the meta token Ref::ATTRIBS is a named GenNode,
and thus trivially responds to isNamed() == true
...instead of using a hand written implementation,
the idea is to rely on the now implemented building blocks,
with just some custom closures to make it work.
- esp. verify the proper inclusion of the Selector closure in all Operations
- straighten the implementation of Attribute binding
- clean-up the error checking helpers
In Theory, acceptSrc and skipSrc are to operate symmetrically,
with the sole difference that skipSrc does not move anything
into the new content.
BUT, since skipSrc is also used to implement the `skip` verb,
which serves to discard garbage left back by a preceeding `find`,
we cannot touch the data found in the src position without risk
of SEGFAULT. For this reason, there is a dedicated matchSrc operation,
which shall be used to generate the verification step to properly
implement the `del` verb.
I've spent quite some time to verify the logic of predicate evaluation.
It seems to be OK: whenever the SELECTOR applies, then we'll perform
the local match, and then also we'll perform the skipSrc. Otherwise,
we'll delegate both operations likewise to the next lower layer,
without touching anything here.
This is the first skeleton to combine all the building blocks,
and it passes compilation, while of course most of the binding
implementation still needs to be filled in...
- default recommendation is to implement DiffMutable interface
- ability to pick up similar non-virtual method on target
- for anything else client shall provide free function mutatorBinding(subject)
PERSONAL NOTE: this is the first commit after an extended leave,
where I was in hospital to get an abdominal cancer removed.
Right now it looks like surgery was successful.
this is at the core of the integration problem: how do we expose
the ability of some opaque data structure to create a TreeMutator?
The idea is
- to use a marker/capability interface
- to use template specialisation to fabricate an instance of that interface
based on the given access point to the opaque data structure
but unfortunately this runs straight into a tough problem,
which I tried to avoid and circumvent all the time:
At some point, we're bound to reveal the concrete type
of the Mutator -- at least to such an extent that we're
able to determine the size of an allocator buffer.
Moreover, by the design chosen thus far, the active
TreeMutator instance (subclass) is assumed to live within
the top-level of a Stack, which means that we need to
place-construct it into that location. Thus, either
we know the type, or we need to move it into place.
the plan is to put together an integration test
of diff application to opaque data through the TreeMutator,
using the now roughly finished binding primitives.
moreover, the idea is to apply precisely the same diff sequence,
as was used in the detail test (TreeMutatorBinding_test).
NOTE: right now, the existing placehoder code applies this sequence
onto a Rec<GenNode>. This should work already -- and it does,
BUT the result of the third step is wrong. Really have to
investigate this accidental finding, because this highlights
a conceptual mismatch in the handling of mixed scopes.
...which mostly just is either ignoring the
operations or indicating failure on attempt to
'reorder' attributes (which don't have any notion of 'ordering')
overall, the structure of this implementation is still rather confusing,
yet any alternatives seem even less convincing
- if we want to avoid the delegation to base-class, we'd have
to duplicate several functions and the combined class would
handle two distinct concerns.
- any attempt to handle the IDs more "symmetrically" seems to
create additional problems on one side or the other
this also supersedes and removes the initial implementation
draft for attribute binding with the 'setAttribute' API
The elementary part of diff application incl. setting
new attribute values works by now.
The way we build this attribute binding, there is no single
entity to handle all attribute bindings. Thus the only way
to detect a missing binding is when none of the binding layers
was able to handle a given INS verb
the idea is again to perform the same sequence of primitives,
this time with a binding to some local variables within the test function
here to enact the role of "object fields"
together with drafting the first segment of the test code,
I've settled down onto an implementation approach
the plan is to use this specific diff sequence
both in the individual binding tests, and in a
more high level integration test. Hopefully this
helps to make these quite technical tests more readable
..as concluded from the preceding analysis.
NOTE this entails a semantical change, since this
predicate is now only meant to be indicative, not conclusive
remarks: the actual implementation of the diff application process
as bound via the TreeMutator remains yet to be written...
how can ordinary object fields be treated as "Attributes"
and thus tied into the Diff framework defined thus far.
This turns out to be really tricky, even questionable
while simple to add into the implementation, this whole feature
seems rather qestionable to me now, thus I've added a Ticket
to be revisited later.
In a nutshell, right here, when implementing the binding layer
for STL collections, it is easy to enable the framework to treat
Ref::THIS properly, but the *actual implementation* will necessarily
be offloaded onto each and every concrete binding implementation.
Thus client code would have to add support for an rather obscure
shortcut within the Diff language. The only way to avoid this
would be to change the semantics of the "match"-lambda: if this
binding would rather be a back-translation of implementation data
into GenNode::ID values, then we'd be able to implement Ref::THIS
natively. But such an approach looks like a way inferiour deisgn
to me; having delegated the meaning of a "match" to the client
seems like an asset, since it is both natural and opens a lot
of flexibility, without adding complexity.
For that reason I tend to avoid that shortcut now, in the hope
to be able to drop it entirely from the language
write down a first draft for a definiton section,
to describe the fundamental parts involved, when
applying a diff message onto implementation defined
data structures
After a break of tree weeks, I found it difficult to find may way
amidst all those various levels of abstraction. In addition to this
definition, we'll probably also need a high level overview of the
whole diff system operation.
...all of this implementation boils down to slightly adjusting
the code written for the test-mutation-target. Insofar it pays off now
having implemented this diagnostic and demonstration first.
Moreover I'm implementing this basic scheme of "diff application"
roughly the fourth time, thus things kindof fall into place now.
What's really hard is all those layers of abstraction in between.
Lesson learned (after being off for three weeks, due to LAC and
other obligations): I really need to document the meaning of the
closures, and I need to document the "abstract operational semantics"
of diff application, otherwise no one will be able to provide
the correct closures.
while I still keep my stance not to allow reflection and
switch-on-type, access to the internal / semantic type of
an embedded record seems a valid compromise to allow
to deal with collections of object-like children
of mixed kind.
Indirectly (and quite intentional) this also opens a loophole
to detect if a given GenNode might constitute a nested scope,
but with the for the actual nested element indeed to cary
a type symbol. Effectively this limits the use of this shortcut
to situations where the handling context does have some pre-established
knowledge about what types *might* be expected. This is precisely
the kind of constraint I intend to uphold: I do not want the
false notion of "total flexibility", as is conveyed by introspection.
the whole implementation will very much be based on
my experiences with the TestMutationTarget and TestWireTap.
Insofar it was a good idea to implement this test dummy first,
as a prototype. Basically what emerges here is a standard pattern
how to implement a tree mutator:
- the TreeMutator will be a one-way-off "throwaway" object.
- its lifecylce starts with sucking away the previous contents
- consuming the diff moves contents back in place
- thus the mutator always attaches onto a target by reference
and needs the ability to manipulate the target
the collection binding can be configured with various
lambdas to supply the basic building blocks of the generated binding.
Since we allow picking up basically anything (functors,
function pointers, function objects, lamdas), and since
we speculate on inlining optimisation of lambdas, we can not
enforce a specific signature in the builder functions.
But at least we can static_assert on the effective signature
at the point where we're generating the actual binding configuration
re-evaluated the decision to build on lambdas, not virtual functions:
- it leads for sure to clearer code at the usag site
- it /might/ offer better, but certainly not worse potential for compiler optimisation
...and write down some insights about the architecure
and design of tree binding and tree description related
to the TreeMutator.
When reading my notes from last year, it became clear
to me that the design of the TreeMutator has evolved
significantly, and became quite something different
than I'd imagined at start
now the full API for the "mutation primitives" is shaped.
Of course the actual implementation is missing, but that
should be low hanging fuit by now.
What still requires some thinking though is how to implement
the selector, so we'll actually get a onion shaped decorator
basically we'll establish a collaboration where both sides
know only the interface (contract) of the partner; a safe margin
for allocation size has to be established through metaprogramming (TODO)
...basically we've now the list mutation primitives working,
albeit in a test/dummy implementation only. Next steps will
be to integrate the assignment and sub scope primitives,
and then to re-do the same implementation respectively
for the case of mutating a standard collection of arbitrary type
now this feels like making progress again,
even when just writing stubs ;-)
Moreover, it became clear that the "typing" of typed child collections
will always be ad hoc, and thus needs to be ensured on a case by case
base. As a consequence, all mutation primitives must carry the
necessary information for the internal selector to decide if this
primitive is applicable to a given decorator layer. Because
otherwise it is not possible to uphold the concept of a single,
abstracted "source position", where in fact each typed sub-collection
of children (and thus each "onion layer" in the decorator chain)
maintains its own private position
after sleeping one night over the problem, this seems to be
the most natural solution, since the possibility of assignment
naturally arises from the fact that, for tree diff, we have
to distinguish between the *identity* of an element node and
its payload (which could be recursive). Thus, IFF the payoad
is an assignable value, why not allow to assign it. Doing so
elegnatly solves the problem with assignment of attributes
Signed-off-by: Ichthyostega <prg@ichthyostega.de>
This basically finishes definition of the fundamental
UI-Element and Bus protocol -- with one notable exception:
how to mutate elements by diff.
This will be the next topic to address
...and I made the decision *not* to consider any kind of
generic properties for now. YAGNI.
UI coding is notorious spaghetti code.
No point in fighting that, it is just the way it is,
because somewhere you're bound to get concrete, hands-on.
