At various places, concepts and drafts from the early stage of the
Lumiera Project are still reflected in the online documentation pages.
During the last months, development focussed on the Render Engine,
causing a shift in some parts of the design, and obsoleting other
parts altogether (notably we consider to use IO_URING for async IO)
The drawing code extracts style information from some "virtual"
widgets, which serve as logical placeholder for the actual nested
structure of tracks.
For sake of demonstration, I used rather obvious colours and
also all kinds of margin and padding; a screenshot was added
with annotations to indicate where some specific style settings
are utilised from the drawing code
.timeline__head : The complete header container on the left side
.timeline__navi : navigation control at top
.timeline__pbay : container holding the patchbay on the left side
.fork__head : each individual TrackHeadWidget (possibly nested)
.fork__control : container for the control components for each track scope
.fork__bracket : the StaveBracket drawing to indicate the nesting structure
We are using buttons now, but the standard theme introduces a lot of padding arount button's contents.
Thus we need to consider ways to address the compound of widgets forming an ElementBox; moreover,
this is the classical situation where the BEM notation helps to clarify the intention....
The problem leading to custom styling here is the padding within buttons;
the default stylesheet seemingly adds a min-width and min-height setting,
and some padding within the Button; based on systematic CSS class names,
it is possible to remove these settings specifically for buttons
within the IDLabel in general (no need to treat only the case of an EventBoxLabel
-- IDLabel could become a custom widget on its own
As we continue with building the backbone of the UI,
and abundance of detail information regaring Layout and styling
will be encountered -- it is tantamount to have a place to
write those findings down....
Further extended GTK code survey to clarify the role of the minimum_size,
it is indeed ignored by most standard containers, but it is actually
used by Gtk::Layout as starting point for the query sequence. Thus
it does not make sense to treat minimum and natural size differently;
both queries should be responded by returning our size constraint.
Unless we define additional borders and margins in the CSS, we can be sure
that GTK will base the size allocation on the exact values returned
from the get_required_* functions.
These functions will be invoked only from within the Event Loop
and after the ctor is finished, but before the first "draw".
They will be re-invoked on each "size change" event and on each
focus change (since a focus change may change the style and thus
the actual extension).
- move construct into the buffer
- directly invoke the payload constructor through PlantingHandle
- reconsider type signature and size constraint
- extend the unit test
- document a corner case of c++ "perfect forwarding",
which caused me some grief here
The population message is just made up, in order to create more interesting structures
in the UI and so to further the development of the timeline display.
For the actual structure I choose to mirror my example drawing in draw/UI-TimelineLayout-1.png
which is also used in the TiddlyWiki, on the #GuiTimelineView tiddler
https://lumiera.org/wiki/renderengine.html#GuiTimelineView
Mostly, std::regexp can be used as a drop-in replacement.
Note: unfortunately ECMA regexps do not support lookbehind assertions.
This lookbehind is necesary here because we want to allow parsing values
from strings with additional content, which means we need explicitly to
exclude mismatches due to invalid syntax.
We can work around that issue like "either line start, or *not* one of these characters.
Alternatively we could consider to make the match more rigid,
i.e we would require the string to conain *only* the timecode spec to be parsed.
- most notably the NOBUG logging flags have been renamed now
- but for the configuration, I'll stick to "GUI" for now,
since "Stage" would be bewildering for an occasional user
- in a similar vein, most documentation continues to refer to the GUI
bottom line is to do most autmatically, and to establish a slave-relation
navigation-area -> timeline-ruler
header-pane-content -> corresponding track-body
this can be accomplished mostly by connecting the aproprieate signals,
thus these widgets will live within the Layout-Manager, which consequently
is renamed into TimelineLayout
...just to decide not to follow-up too much on that topic right now.
As it turns out, GTK seems to be lacking in that respect. I have plotted
some ideas how we could work around that discrepancy in future...
And for this simple DemoGuiRoundtrip, we'll just use direct styling,
but we'll store a table of bookmarks for the error entries, allowing
us to add further features later on top
In the end, I decided against building a generic service here,
since it pretty much looks like a one-time problem.
Preferrably UI content will be pushed or pulled on demand,
rather than actively coding content from within the UI-Layer
- activation signal is a facility offered and used solely by Gtk::Application
- we do not need nor want an Gtk::Application, we deal with our own application
concerns as we see fit.
- polish the text in the TiddlyWiki
- integrate some new pages in the published documentation
Still mostly placeholder text with some indications
- fill in the relevant sections in the overview document
- adjust, expand and update the Doxygen comments
TODO: could convert the TiddlyWiki page to Asciidoc and
publish it mostly as-is. Especially the nice benchmarks
from yesterday :-D
As it turned out, we had two bugs luring in the code base,
with the happy result of one cancelling out the adverse effects of the other
:-D
- a mistake in the invocation of the Itertools (transform, filter,...)
caused them to move and consume any input passed by forwarding, instead
of consuming only the RValue references.
- but util::join did an extraneous copy on its data source, meaning that
in all relevant cases where a *copy* got passed into the Itertools,
only that spurious temporary was consumed by Bug #1.
(Note that most usages of Itertools rely on RValues anyway, since the whole
point of Itertools is to write concise in-line transformation pipelines...)
*** Added additional testcode to prove util::stringify() behaves correct
now in all cases.
surprising behaviour encountered while covering more cases
...obviously the return type of ExpandFunctor::operator()
was inferred as value, even while the invoked functor, from which
this type was deduced, clearly returns a reference.
Solution is simple not to rely on inference, moreover since we know
the exact type in the enclosing scope, thanks to the refactoring which
made this ExpandFunctor a nested class
NOTE:
as it turned out, this is not a compiler bug,
but works as defined by the language:
on return type inference, the detected type is decayed,
which usually helps to prevent returning a reference to a temporary
this becomes more relevant now, since the actual MutationMessage iterators
are implemented in terms of a shared_ptr to IterSource. Thus, when building
processing pipelines, we most definitively want to move that smart-ptr into
the destination, since this avoids touching the shared count and thus avoids
generating unnecessary memory barriers.
obsoleted by C++11
* in most cases, it can be replaced by an explicit conversion operator
* especially for the Lumiera Forward Iterators, we need an implicit conversion
...because of questionable utility
And it turned out to be quite a liability when it comes to implementing
the building blocks for binding tree implementation data structures
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
