the original construction works only as long as we stick to the "classical" Builder syntax,
i.e. use chained calls of the builder functions. But as soon as we just invoke
some builder function for sake of the side-effect on the data within the builder,
this data is destroyed and moved out into the value return type, which unfortunately
is being thrown away right afterwards.
Thus: either make a builder really sideeffect-free, i.e. do each mutation
on a new copy (which is kind of inefficient and counterfeits the whole idea)
or just accept the side-effect and return only a reference.
In this case, we can still return a rvalue-Reference, since at the end
we want to move the product of the build process out into the destination.
This works only due to the C++ concept of sequence points, which ensures
the original object stays alive during the whole evaluation of such a chained
builder expression.
NOTE: the TreeMutator (in namespace lib::diff) also uses a similar Builder construction,
but in *that* case we really build a new product in each step and thus *must*
return a value object, otherwise the reference would already be dangling the
moment we leave the builder function.
- the default should be to look for total coverage
- the predicates should reflect the actual state of the path only
- the 'canXXX' predicates test for possible covering mutation
I set out to "discover" what operations we actually need on the LocationQuery
interface, in order to build a "coordinate resolver" on top. It seems like
this set of operations is clear by now.
It comes somewhat as a surprise that this API is so small. This became possible
through the idea of a ''child iterator'' with the additional ability to delve down and
expand one level of children of the current element. Such can be ''implemented''
by relying on techniques similar to the "Monads" from functional programming.
Let's see if this was a good choice. The price to pay is a high level of ''formal precision''
when dealing with the abstraction barrier. We need to stick strictly to the notion of a
''logical path'' into a tree-like topology, and we need to be strong enough never to
give in and indulge with "the concrete, tangible". The concrete reality of a tree
processing algorithm with memory management plus backtracking is just to complex
to be handled mentally. So either stick to the rules or get lost.
yet some more trickery to get around this design problem.
I just do not want to rework IterSource right now, since this will be
a major change and require more careful consideration.
Thus introduce a workaround and mark it as future work
Using this implementation, "child expansion" should now be possible.
But we do not cover this directly in Unit test yet
we need to layer our Navigator implementation on top,
since this object needs to capture a reference to the "current position".
This is necessary to be able to derive the child position by extending
and then to form a child navigator -- which is the essence of
implementing expandChildren()
...but not yet switched into the main LocationQuery interface,
because that would also break the existing implementation;
recasting this implementation is the next step to do....
...which basically allows us to return any suitable implementation
for the child iterator, even to switch the concrete iteration on each level.
We need this flexibility when implementing navigation through a concrete UI
...at least when using a wrapped Lumiera Iterator as source.
Generally speaking, this is a tricky problem, since real mix-in interfaces
would require the base interface (IterSource) to be declared virtual.
Which incurres a performance penalty on each and every user of IterSource,
even without any mix-in additions. The tricky part with this is to quantify
the relevance of such a performance penalty, since IterSource is meant
to be a generic library facility and is a fundamental building block
on several component interfaces within the architecture.
...yet I do not want to move all of the traits over into the
publicly visible lib::iter_explorer namespace -- I'm quite happy
with these traits being clearly marked as local internal details
NOTE it just type checks right now,
but since meta programming is functional programming, this means
with >90% probability that it might actually work this way....
...which also happens to include sibling and child iteration;
this is an attempt to reconcile the inner contradictions of the design
(we need both absolute flexibility for the type of each child level iterator
yet we want just a single, generic iterator front-end)
...this was a difficult piece of consideration and analysis.
In the end I've settled down on a compromise solution,
with the potential to be extended into the right direction eventually...
surprise: the standard for-Loop causes a copy of the iterator.
From a logical POV this is correct, since the iterator is named,
it can not just be moved into the loop construct and be consumed.
Thus: write a plain old-fashioned for loop and consume the damn thing.
So the top-level call into util::join(&&) decides, if we copy or consume
several extensions and convenience features are conceivable,
but I'll postpone all of them for later, when actual need arises
Note especially there is one recurring design challenge, when creating
such a demand-driven tree evaluation: more often than not it turns out
that "downstream" will need some information about the nested tree structure,
even while, on the surfice, it looks as if the evaluation could be working
completely "linearised". Often, such a need arises from diagnostic features,
and sometimes we want to invoke another API, which in turn could benefit
from knowing something about the original tree structure, even if just
abstracted.
I have no real solution for this problem, but implementing this pipeline builder
leads to a pragmatic workaround: since the iterator already exposes a expandChildren(),
it may as well expose a depth() call, even while keeping anything beyond that
opaque. This is not the clean solution you'd like, but it comes without any
overhead and does not really break the abstraction.
...so sad.
The existing implementation was way more elegant,
just it discarded an exahusted parent element right while in expansion,
so effectively the child sequence took its place. Resolved that by
decomposing the iterNext() operation. And to keep it still readable,
I make the invariant of this class explicit and check it (which
caught yet another undsicovered bug. Yay!)
instead of building a very specific collaboration,
rather just pass the tree depth information over the extended iterator API.
This way, "downstream" clients *can* possibly react on nested scope exploration
...and there is a point where to stop with the mere technicalities,
and return to a design in accordance with the inner nature of things.
Monads are a mere technology, without explicatory power as a concept or pattern
For that reason
- discard the second expansion pattern implemented yesterday,
since it just raises the complexity level for no given reason
- write a summary of my findings while investigating the abilities
of Monads during this design excercise.
- the goal remains to abandon IterExplorer and use the now complete
IterTreeEplorer in its place. Which also defines roughly the extent
to wich monadic techniques can be useful for real world applications
...it can sensibly only be done within the Expander itself.
Question: is this nice-to-have-feature worth the additional complexity
of essentially loading two quite distinct code paths into a single
implementation object?
As it stands, this looks totally confusing to me...
At that time, our home-made Tuple type was replaced by std::tuple,
and then the command framework was extended to also allow command invocation
with arguments packaged as lib::diff::Record<GenNode>
With changeset 0e10ef09ec
A rebinding from std::tuple<ARGS...> to Types<ARGS> was introduced,
but unfortunately this was patched-in on top of the existing Types<ARGS...>
just as a partial specialisation.
Doing it this way is especially silly, since now this rebinding also kicks
in when std::tuple appears as regular payload type within Types<....>
This is what happened here: We have a Lambda taking a std::tuple<int, int>
as argument, yet when extracting the argument type, this rebinding kicks in
and transforms this argument into Types<int, int>
Oh well.
this leads to either unfolding the full tree depth-first,
or, when expanding eagerly, to delve into each sub-branch down to the leaf nodes
Both patterns should be simple to implement on top of what we've built already...
IterSource should be refactored to have an iteration control API similar to IterStateWrapper.
This would resolve the need to pass that pos-pointer over the abstraction barrier,
which is the root cause for all the problems and complexities incurred here
...but for now the price is that we need to punch a hole into IterAdapter.
And obviously, this is all way to tangled and complex on implementation level.
this was a design decision, but now I myself run into that obvious mistake;
thus not sure if this is a good design, or if we need a dedicated operation
to finish the builder and retrieve the iterable result.
as it turned out, when "inheriting" ctors, C++14 removes the base classes' copy ctors.
C++17 will rectify that. Thus for now we need to define explicitly that
we'll accept the base for initialising the derived. But we need do so
only on one location, namely the most down in the chain.
Since this now requires to import iter-adapter-stl.hpp and iter-source.hpp
at the same time, I decided to drop the convenience imports of the STL adapters
into namespace lib. There is no reason to prefer the IterSource-based adapters
over the iter-adapter-stl.hpp variants of the same functionality.
Thus better always import them explicitly at usage site.
...actual implementation of the planned IterSource packaging is only stubbed.
But I needed to redeclare a lot of ctors, which doesn't seem logical
And I get a bad function invocation from another test case which worked correct beforehand.
