An extended series of refactoring and partial rewrites resulted
in a new definition of the `Dispatcher` interface and completes
the buildup of a Job-Planning pipeline, including the ability
to discover prerequisites and compute scheduling deadlines.
At this point, I am about to ''switch to the topic'' of the `Scheduler`,
''postponing'' the completion of the `RenderDrive` until the related
questions regarding memory management and Scheduler interface are settled.
...as a preparation for solving a logical problem with the Planning-Pipeline;
it can not quite work as intended just by passing down the pair of
current ticket and dependent ticket, since we have to calculate a chained
calculation of job deadlines, leading up to the root ticket for a frame.
My solution idea is to create the JobPlanning earlier in the pipeline,
already *before* the expansion of prerequisites, and rather to integrate
the representation of the dependency relation direcly into JobPlanning
...using hard coded values instead of observation of actual runtimes,
but at least the calculation scheme (now relocated from TimeAnchor to JobPlanning)
should be a reasonable starting point.
TODO: test fails...
- has to be prepared / supported by the RenderEnvironmentClosure
- actual translation happens when building the Dispatcher-Pipeline
- implementation delegate through
virtual size_t Dispatcher::resolveModelPort (ModelPort)
...it turns out that we actually do not need to wrap TreeExplorer
on the builder types, because basically there is only a single active
builder type, and the complete processing pipeline can be assembled
in a single terminal function.
The type rebinding problem can thus be solved just by a simple
marker struct, which inherits from a template parameter
...which leads to the next daunting problems:
- we need some mocked ModelPort and DataSink placeholders
- we need a way how to inherit from a partial TreeExplorer pipeline
- introduce a JobTicket::NOP (null-object pattern)
- assuming that the function splitSplice() will retain complete coverage allways
Remark:
`Fixture::getPlaylistForRender()` is a leftover from the very early implementation drafts.
This function was more or less based on the way Cinelerra works; it is clear by now
that Lumiera can not possibly work this way, given that we'll build a low-level model
and dispatch precompiled render jobs....
- decision: the Monad-style iteration framework will be abandoned
- the job-planning will be recast in terms of the iter-tree-explorer
- job-planning and frame dispatch will be disentangled
- the Scheduler will deliberately offer a high-level interface
- on this high-level, Scheduler will support dependency management
- the low-level implementation of the Scheduler will be based on Activity verbs
the reason for the failure, as it turned out,
is that 'noexcept' is part of the function signature since C++17
And, since typically a STL container has const and non-const variants
of the begin() and end() function, the match to a member function pointer
became ambuguous, when probing with a signature without 'noexcept'
However, we deliberately want to support "any STL container like" types,
and this IMHO should include types with a possibly throwing iterator.
The rationale is, sometimes we want to expose some element *generator*
behind a container-like interface.
At this point I did an investigation if we can emulate something
in the way of a Concept -- i.e. rather than checking for the presence
of some functions on the interface, better try to cover the necessary
behaviour, like in a type class.
Unfortunately, while doable, this turns out to become quite technical;
and this highlights why the C++20 concepts are such an important addition
to the language.
So for the time being, we'll amend the existing solution
and look ahead to C++20
as it turns out, "almost" the whole codebase compiles in C++17 mode.
with the exception of two metaprogramming-related problems:
- our "duck detector" for STL containers does not trigger anymore
- the Metafunction to dissect Function sigantures (meta::_Fun) flounders
