...based on a monadic tree expansion: we define a single step,
which takes the current filter configuration and builds the next
filter configuration, based on a stored chain of configuration functions
The actual exhausting depth-first results just by the greedy application pattern,
and uses the stack embedded in the "Explorer" layer of TreeExplorer
..this resolves the most challenging part of the construction work;
we use the static helper functions to infer a type and construct a suitable
processing pipeline and we invoke the same helper to initialise the base class
in the ctor.
Incidentally... we can now drop all the placeholder stubs,
since we now inherit the full iterator and child explorer API.
The test now starts actually to work... we get spam and sausage!
TODO: now actually fill in the expand functor such as to pick the
concrete filter step in the chain from a sequence of preconfigured
filter bindings
...now matters start to get really nasty,
since we have to pick up an infered type from a partially built pipeline
and use it to construct the signature for a functor to bind into the more elaborate complete pipeline
this is a tricky undertaking, since our treeExplore() helper constructs
a complex wrapped type, depending on the actual builder expressions used.
Solution is to use decltype on the result of a helper function,
and let the _DecoratorTraits from TreeExplorer do the necessary type adaptations
...it should have been this way all the time.
Generic code might otherwise be ill guided to assume a conversion
from the Iterator to its value type, while in fact an explicit dereferentiation is necessary
The intention is to augment the iterator based (linear) search
used in EventLog to allow for real backtracking, based on a evaluation tree.
This should be rather staight forward to implement, relying on the
exploreChildren() functionality of TreeExplorer. The trick is to package
the chained search step as a monadic flatMap operation
we did an unnecessary copy of the argument, which was uncovered
by the test case manipulating the state core.
Whew.
Now we have a beautiful new overengineered solution
outift the Filter base class with the most generic form of the Functor
wrapper, and rather wrap each functor argument individually. This allows
then to combine various kinds of functors
...this solution works, but has a shortcoming:
the type of the passed lambdas is effectively pinned to conform
with the signature of the first lambda used initially when building the filter.
Well, this is the standard use case, but it kind of turns all the
tricky warpping and re-binding into a nonsense excercise; in this form
the filter can only be used in the monadic case (value -> bool).
Especially this rules out all the advanced usages, where the filter
collaborates with the internals of the source.
while this is basically just code code cosmetics,
at least it marks this as a very distinct special case,
and keeps the API for the standard Filter layer clean.
a quite convoluted construct built from several nested generic lambdas.
When investigated in the debugger, the observed addresses and the
invoked code looks sane and as expected.
The intention is to switch from the itertools-based filter
to the filter available in the TreeExplorer framework.
Thus "basically" we just need to copy the solution over,
since both are conceptually equivalent.
However...... :-(
The TreeExplorer framework is designed to be way more generic
and accepts basically everything as argument and tries to adapt apropriately.
This means we have to use a lot of intricate boilerplate code,
just to get the same effect that was possible in Itertools with
a simple and elegant in-place lambda assignment
Fillter needs to be re-evaluated, when an downstream entity requests
expandChildren() onto an upstream source. And obviously the ordering
of the chained calls was wrong here.
As it turns out, I had discovered that necessity to re-evaluate with
the Transformer layer. There is a dedicated test case for that, but
I cut short on verifying the filter in that situation as well, so
that piece of broken copy-n-paste code went through undetected.
This is in fact a rather esoteric corner case, because it is only
triggered when the expandChildren() call is passed through the filter.
When otoh the filter sits /after/ the entity generating the expandChildren()
calls, everything works as intended. And the latter is the typical standard
usage situation of an recursive evalutation algorithm: the filter is here
used as final part to drive the evaluation ahead and pick the solutions.
There is a bug or shortcoming in the existing ErrorLog matcher implementation.
It is not really difficult to fix, however doing so would require us to intersperse
yet another helper facility into the log matcher. And it occurred to me, that
this helper would effectively re-implement the stack based backtracking ability,
which is already present in TreeExplorer (and was created precisely to support
this kind of recursive evaluation strategies).
Thus I intend to switch the implementation of the EventLog matcher from the
old IterTool framework to the newer TreeExplorer framework. And this intention
made me re-read the code, fixing several comments and re-thinking the design
seemingly my quick-n-dirty implementation was to naiive.
We need real backtracking, if we want to support switches
in the search direction (match("y").after("x").before("z")
Up to now, I have cheated myself around this obvious problem :-/
Greedy wildcard match .+ is unnecessary, since in case of a positive match,
the next given expression always follows immediately. We just want to skip
over some "syntactic noise"
This change makes the matching time linear in the size of the log.
But unfortunately, I still occasionally see an Segmentation Fault.
It seems to arise when compiling the regular expresions
e.g. the following RegExps cashed (right in the middle of the test)
after.+?_ATTRIBS_.+?ins.+?53 of 57 ≺358.gen010≻.+?mut.+?53 of 57 ≺358.gen010≻.+?ins.+?borgID.+?358.+?emu.+?53 of 57 ≺358.gen010≻
after.+?_ATTRIBS_.+?ins.+?53 of 63 ≺178.gen028≻.+?mut.+?53 of 63 ≺178.gen028≻.+?ins.+?borgID.+?178.+?emu.+?53 of 63 ≺178.gen028≻
after.+?_ATTRIBS_.+?ins.+?53 of 59 ≺498.gen038≻.+?mut.+?53 of 59 ≺498.gen038≻.+?ins.+?borgID.+?498.+?emu.+?53 of 59 ≺498.gen038≻
after.+?_ATTRIBS_.+?ins.+?53 of 60 ≺223.gen003≻.+?mut.+?53 of 60 ≺223.gen003≻.+?ins.+?borgID.+?223.+?emu.+?53 of 60 ≺223.gen003≻
after.+?_ATTRIBS_.+?ins.+?53 of 78 ≺121.gen015≻.+?mut.+?53 of 78 ≺121.gen015≻.+?ins.+?borgID.+?121.+?emu.+?53 of 78 ≺121.gen015≻
This finishes the first round of design drafts in this area.
Right now it seems difficult to get any further, since most of
the actual view creation and management in the UI is not yet coded.
The boost::hash documentation does not mention a significant change in that area,
yet the frequent collisions on identifiers with number suffix do not occur anymore
in Boost 1.65
On rare occasions, the test thread itself consumes faster than the producer threads feed new test data.
Make sure the test does not hangin such a situation
The original goal for #1129 (ViewSpecDSL_test) is impossible to accomplish,
at least within our existing test framework. Thus I'll limit myself to coding
a clean-room integration test with purely synthetic DSL definitions and mock widgets
...still quite braindead, but allows at least to cover the standard case as well.
A better mock element access service would at least traverse a GenNode-Tree,
and thus emulate the behaviour of the real service; yet both seems way beyond
scope right now, and all I need is some basic coverage of the Interface
My understanding is that in the standard use case, we precisely know what to expect
and just go ahead and perform the conversion. Thus it is pointless to introduce
fine grained distinctions. When the access fails, this always indicates some broken
application logic, and just raises an error.
With this solution, somewhere deep down within the implementation
the knowledge about the actual result type would be encoded into
the embedded VTable within a lib::variant. At interface level,
ther will be a double dispatch based on that result type
and the desired result type, leading either to a successful
access or an error response.
Basically the mocking mechanism just switches the configuration
and then waits for the service to be accessed in order to cause acutual
instantiation of the mock service implementation. But sometimes we want
to prepare and rig the mock instance prior to the first invocation;
in such cases it can be handy just to trigger the lazy creating process
Attempt to find my way back to the point
where the digression regarding dependency-injection started.
As it turns out, this was a valuable digression, since we can rid ourselves
from lots of ad-hoc functionality, which basically does in a shitty way
what DependencyFactory now provides as standard solution
FIRST STEP is to expose the Navigator as generic "LocationQuery" service
through lib::Depend<LocationQuery>
I am fully aware this change has some far reaching ramifications.
Effectively I am hereby abandoning the goal of a highly modularised Lumiera,
where every major component is mapped over the Interface-System. This was
always a goal I accepted only reluctantly, and my now years of experience
confirm my reservation: it will cost us lots of efforts just for the
sake of being "sexy".
...and package the ZombieCheck as helper object.
Also rewrite the SyncClassLock_test to perform an
multithreaded contended test to prove the lock is shared and effective
- state-of-the-art implementation of access with Double Checked Locking + Atomics
- improved design for configuration of dependencies. Now at the provider, not the consumer
- support for exposing services with a lifecycle through the lib::Depend<SRV> front-end
...which declare DependencyFactory as friend.
Yes, we want to encourrage that usage pattern.
Problem is, std::is_constructible<X> gives a misleading result in that case.
We need to do the instantiation check within the scope of DependencyFactory
ideally we want
- just a plain unique_ptr
- but with custom deleter delegating to lib::Depend
- Depend can be made fried to support private ctor/dtor
- reset the instance-ptr on deletion
- always kill any instance
all these tests are ported by drop-in replacement
and should work afterwards exactly as before (and they do indeed)
A minor twist was spotted though (nice to have more unit tests indeed!):
Sometimes we want to pass a custom constructor *not* as modern-style lambda,
but rather as direct function reference, function pointer or even member
function pointer. However, we can not store those types into the closure
for later lazy invocation. This is basically the same twist I run into
yesterday, when modernising the thread-wrapper. And the solution is
similar. Our traits class _Fun<FUN> has a new typedef Functor
with a suitable functor type to be instantiated and copied. In case of
the Lambda this is the (anonymous) lamda class itself, but in case of
a function reference or pointer it is a std::function.
...which showed up under high system load.
The initialisation of the member variables for the check sum
could be delayed while the corresponding thread was already running
...written as byproduct from the reimplementation draft.
NOTE there is a quite similar test from 2013, DependencyFactory_test
For now I prefer to retain both, since the old one should just continue
to work with minor API adjustments (and thus prove this rewrite is a
drop-in replacement).
On the long run those two tests could be merged eventually...
decided to add a very specific preprocessing here, to make the DSL notation more natural.
My guess is that most people won't spot the presence of this tiny bit of magic,
and it would be way more surprising to have rules like
UICoord::currentWindow().panel("viewer").create()
fail in most cases, simply because there is a wildcard on the perspective
and the panel viewer does not (yet) exist. In such a case, we now turn the
perspective into a "existential quantified" wildcard, which is treated as if
the actually existing element was written explicitly into the pattern.
...actually just more test coverage,
the feature is already implemented.
What *could* be done though is to inject that UIC_ELIDED marker
on missing perspective specs in create clauses automatically...
This looks like YAGNI, and it would be non trivial to implement.
But since the feature looks important for slick UI behaviour,
I've made a new ticket and leave it for now
with the exception of some special situations,
which require additional features from the engine,
especially binding-on-context
Not sure though if I'll implement these or say YAGNI
- 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.
...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.
This is just a temporary solution, until IterSource is properly refactored (#1125)
After that, IterSource is /basically a state core/ and the adaptor will be more or less trivial
- as it stands currently, IterSource has a design problem, (see #1125)
- and due to common problems in C++ with mix-ins and extended super interfaces,
it is surprisingly tricky to build on an extension of IterSource
- thus the idea is to draft a new solution "in green field"
by allowing TreeExplorer to adapt IterSource automatically
- the new sholution should be templated on the concrete sub interface
and ideally even resolve the mix-in-problem by re-linearising the
inheritance line, i.e. replace WrappedLumieraIter by something
able to wrap its source, in a similar vein as TreeExplorer does
...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...
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
We get conflicting goals here:
- either the child expansion happens within the opaque source data
and is thus abstracted away
- or the actual algorithm evaluation becomes aware of the tree structure
and is thus able to work with nested evaluation contexts and a local stack
...build on top of the core features of TreeExplorer
- completely encapsulate and abstract the source data structure
- build an backtracking evaluation based on layered evaluation
of this abstracted expandable data source
NOTE: test passes compilation, but doesn't work yet
...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
turns out that -- again -- we miss some kind of refresh after expanding children.
But this case is more tricky; it indicates a design mismatch in IterSource:
we (ab)use the pos-pointer to communicate iteration state. While this might be
a clever trick for iterating a real container, it is more than dangerous when
applied to an opaque source state as in this case. After expanding children,
the pos-pointer still points into the cache buffer of the last transformer.
In fact, we miss an actualisation call, but the IterSource interface does not
support such a call (since it tries to get away with state hidden in the pos pointer)
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.
due to switching from ADL extension points to member functions,
we now need to detect a "state core" type in a different fashion.
The specific twist is that we can not spell out the full signature
in all cases, since the result type will be formed as a consequence
of this type detection. Thus there are now additional detectors to
probe for the presence of a specific function name only, and the
distinction between members and member functions has been sharpened.
