...to limit them to the UI-Coordinates themselves,
while declining the possibility to mutate the target environment
through the PathResolver. Better handle changes within the
target environment by dedicated API calls on the target elements,
instead of creating some kind of "universal structure"
..this collection of ideas, terms and conclusions has been shaped
since some time within the TiddlyWiki. Since I've now started even
some supporting implementation regarding these concepts, its time
to publish them in the design documentation section of the Website
After completing the self-contained UICoord data elements,
the next thing to consider might be how to resolve UI coordinates
against an actual window topology. We need to define a suitable
command-and-query interface in order to build and verify this
intricate resolution process separated from the actual UI code.
...we have to face the problem that we need some generic strategy
for access to component views, which possibly will become customisable.
And the allowed patterns of access are quite different for the various
kind of view we know....
this starts work on a new UI global topic (#1004)
- coin a new term: "view component"
- distinction between veiw component and Panel
- consider how to locate view components
- WindowList becomes WindowLocator
This change was caused by investigation of UI event loop dispatch;
since the GTK UI is designed to run single threaded, any invocation
from other threads need to be diepatched explicitly.
A possible way to achieve this is to use Glib::Dispatcher, which
in turn requires that the current thread (which is in this case the UI thread)
already holds a Glib::MainContext
This prompted me to create a tight link between the external facade interfaces
of the UI and the event loop itself. What remains to be settled is how
to hand over arguments to the action in the main loop
After investigation of current GTK and GIO code, I came to the conclusion
that we do *not* want to rely on the shiny new Gtk::Application, which
provides a lot of additional "convenience" functionality we do neither
need nor want. Most notably, we do not want extended desktop integration
like automatically connecting to D-Bus or exposing application actions
as desktop events.
After stripping away all those optional functions and extensions, it turns
out the basic code to operate the GTK main event loop is quite simple.
This changeset extracts this code from the (deprecated) Gtk::Main and
integrates it directly in Lumiera's UI framework object (UiManager).
as it turned out, the former functionality was deactivated in 2009
with changeset 6151415
The whole concept seems to be unfinished, and needs to be reworked
and integrated with "Views and Perspectives" (whatever that is...)
See also #1097
after extended analysis, it turned out to be a "placeholder concept"
and introduces an indirection, which can be removed altogether
- simple command invocation happens at gui::model::Tangible
- it is based on the command (definition) ID
- instance management happens automatically and transparently
- the extended case of context-bound commands will be treated later,
and is entirely self-contained
while the initial design treated the commands in a strictly top-down manner,
where the ID is known solely to the CommandRegistry, this change and information
duplication became necessary now, since by default we now always enqueue and
dispatch anonymous clone copies from the original command definition (prototype).
This implementation uses the trick to tag this command-ID when a command-hanlde
is activated, which is also the moment when it is tracked in the registry.
as it turns out, we can always trigger commands right away,
the moment all arguments are known. Thus it is sufficient to
send a single argument binding message, which allows us to
get rid of a lot or ugly complexities (payload visitor).
interesting new twist: we do not even need to decorate with a running number,
since we'll get away with an anonymous command instance, thanks to Command
being a smart-handle
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
...because this topic serves as a vehicle to elaborate various core concepts
of the UI backbone, especially how to access, bind and invoke Proc-Layer commands
...turns out to be a nasty subject, now we're able to see
in more concrete detail how this interaction needs to be carried out.
Basically this is a blocker for the top-level, since it is obviously
some service in top-level, which ultimately becomes responsible for
orchestrating this activity
After quite some pondering, it occured to me that we both
- need some top-level model::Tangible to correspond to the RootMO in the session
- need some Controller to handle globally relevant actions
- need a way to link action invocation to transient interaction state (like focus)
This leads to the introduction of a new top-level controller, which is better
suited to fill that role than the depreacted model-controller or the demoted window-manager
looks like we're in management business here ;-)
we chop off heads, slaughter the holy cows and then install -- a new manager
This is a very pervasive change and basically turns the whole top-level
of the GTK-UI bottom-up. If this change turns out right, it would likely
solve #1048
WARNING: in parts not implemented, breaks UI
Now I've realised that there are two degrees of connectedness.
It is very much possible to have a "free standing" BusTerm, which
only allows to send uplink messages. In fact, this is how CoreService
is implemented, and probably it should also the way how to connect
the GuiNotification service...
Writing and debugging such tests is always an interesting challenge...
Fortunately this exercise didn't unveil any problem in the newly written
code, only some insidious problems in the test fixture itself. Which
again highlights the necessity, that each *command instance* needs
to be an independent clone from the original *command prototype*,
since argument binding messages and trigger messages can appear
in arbitrary order.
not quite sure how to get the design straight.
Also a bit concerned because we'll get this much indirections;
the approach to send invocations via the UI-Bus needs to prove its viability
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
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
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
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
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...
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
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
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
..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
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.
...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
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
not sure yet if any of this works, because the
technicalities of dealing with variadic types are
quite different to our LISP-style typelist processing.
The good news is that with variadic templates it is
indeed possible, to supply dynamically picked arguments
to another function taking arbitrary arguments.
This all relies on the feature to unpack argument packs,
and, more specifically, about the possiblity to "wrap"
this unpacking around interspersed function call syntax
template<size_t...i>
Xyz
do_something(MyTuple myTuple)
{
return Xyz (std::get<i> (myTuple) ... );
}
Here the '...' will be applied to the i... and then
the whole std::get-construct will be wrapped around
each element. Mind bogging, but very powerful
next step will be to rig the mock element and set up
and cover the basic / generic element behaviour
This changeset
- adapts the (planned) unit test to the semantic of
the EventLog, which is now fully implemented
- adjusts the function names on the public Tangible interface,
to be better in line with the naming convention of the
corrsponding operations on the UI-Bus:
* "mark" operations are towards the UI element
* "note" messages are from the UI element towards some
state manager, which can be reached via the bus
what you see here now is just the tip of the icebearg...
If we follow this route, the Lumiera UI will become way more
elaborate and responsive than average desktop applications
initially my intention was to use the ID for equality test.
But on a second thought, this seemed like a bad idea, since
it confuses the concepts of equality and identity.
Note: at the moment, I do not know if we even need an equality test,
so it is provided here rather for sake of completeness. And this
means even more that we want an 'equality' implementation that
does what one would naively expect: compare the object identity
*and* compare the contents.
especially I've now decided how to handle const-ness:
We're open to all forms of const-ness, the actual usage decides.
const GenNode will only expose a const& to the data values
still TODO is the object builder notation for diff::Record
for the purpose of working out the inner logic, I frequently use the
help of a mindmap -- so why not commiting this alongside? For sure,
it is preliminary and the worked out concepts will be cast in code
and documented on the website. Yet the thought-process leading to
these decisions might be of some interest, at least for myself.
before engaging into the implementation of lib::Record,
I prefer to conduct a round of planning, to get a clearer
view about the requirements we'll meet when extending
our existing list diff to tree structures
Introduce the new term "Fork" at various relevant places
within the documentation. We do not entirely purge the
term "track" though; rather we
- make clear that "Fork" is the entity to build tracks
- use "fork" also synonymous to the "tree of tracks"
