...passes the simplest unit test
* create a Several<int>
* populate from `std::initializer_list`
* random-access to elements
''next step would be to implement iteration''
Some decisions
- use a single template with policy base
- population via separate builder class
- implemented similar to vector (start/end)
- but able to hold larger (subclass) objects
- basically works out-of-the-box now
- the hard wired fixed Extent size is a serious limitation
- however, this is not the intended primary use, rather complementary
...this is an important detail: quite commonly, a custom allocator
is actually implemented as monostate, to avoid bloating every client container
with a backlink pointer; by inheriting the `StdFactory` adapter from the
allocator, the empty-base optimisation can be exploited.
In the standard case thus LinkedElements is the same size as a single
pointer, which is already exploited at several places in the code base.
Notably `AllocationCluster` uses a »virtual overlay« to dress-up the
position pointer as `LinkedElements`, allowing to delegate most of the
administration and memory management to existing and verified code.
With this adjustments, `LinkedElements` pass the tests again
and the rework of `AllocationCluster` is considered complete.
This is the first validation of the new design:
the policy to take ownership can be reimplemented simply
by delegating to the adaptor for a C++ standard allocator
...what I've implemented yesterday is effectively the same functionality
as provided automatically by the C++ object system when using a virtual destructor.
Thus a much cleaner solution is to turn `Destructor` into a interface
and let C++ do all the hard work.
Verified in test: works as intended
This is the first draft, implementing the invocation explicitly
through a trampoline function. While it seems to work,
the formulation can probably be simplified....
- rather accept hard-wired limits than making the implementation excessively generic
- by exploiting the layout, the administrative overhead can be reduced significantly
- the trick with the "virtual managment overlay" allows to hand-off most of the
clean-up work to C++ destructor invocation
- it is important to verify these low-level arrangements explicitly by unit-test
...due to the decision to use a much simpler allocation scheme
to increase probability for actual savings, after switching the API
and removing all trading related aspects, a lot of further code is obsoleted
Notably this raises the difficult question,
whether to ensure **invocation of destructors**.
Not invoking dtors ''breaks one of the most fundamental contracts''
of the C++ language — yet the infrastructure to invoke dtors in such
a heterogeneous cluster of allocations creates a hugely significant
overhead and is bound to poison the caches (objects to be deallocated
typically sit in cold memory pages).
What makes this decision especially daunting is the fact that the
low-level-Model can be expected to be one of the largest systemic
data structures (letting aside the media buffers).
I am leaning towards a compromise: turn down this decision
towards the user of the `AllocationCluster`
At the time of the initial design attempts, I naively created a
classic interface to describe an fixed container allocated ''elsewhere.''
Meanwhile the C++ language has evolved and this whole idea looks
much more as if it could be a ''Concept'' (C++20). Moreover, having
several implementations of such a container interface is deemed inadequate,
since it would necessitate ''at least two indirections'' — while
going the Concept + Template route would allow to work without any
indirection, given our current understanding that the `ProcNode` itself
is ''not an interface'' — rather a building block.
After a lot of further tinkering, seemingly arriving at a
somewhat satisfactory solution for the layout and arrangement of
test definitions and especially the table for measurement series.
While the complete setup remains fragile indeed, and complexity is more
hidden than reduced — the pragmatic compromise established yesterday
at least allows to reduce the amount of boilerplate in the test or
measurement setup to make the actual specifics stand out clearly.
----
As an aside, the usage of the `DataFile` type imported from Yoshimi-test
recently was re-shaped more towards a generic handling of tabular data with
CSV storage option; thus renaming the type now into `DataTable`.
Persistent storage is now just one option, while another usage pattern
compounds observation data into table rows, which are then directly
rendered into a CSV string, e.g. for visualisation as Gnuplot graph.
...which is added automatically whenever additional data columns are present
Result can only be verified visually
* the upper diagram should show the first fibonacci points
* a (correct) linear regression line should be overlayed in red
* below, a secondary diagram should appear, with aligned axis
* the row "one" in this diagram should be shown as impulses
* the further rows "two" and "three" should be drawn as
green points, using the secondary Y-axis (values 100-250)
* Gnuplot can handle missing data points
The idea is to build the Layout-branching into the generated Gnuplot script,
based on the number of data columns detected. If there is at least one further
data column, then the "mulitplot" layout will be used to feature this
additional data in a secondary diagram below with aligned axis;
if more than one additional data column is present, all further
visualisation will draw points, using the secondary Y-axis
Moreover, Gnuplot can calculate the linear regresssion line itself,
and the drawing will then be done using an `arrow` command,
defining a function regLine(x) based on the linear model.
- `forElse` belongs to the metaprogramming utils
- have a CSVLine, which is a string with custom appending mechanism
- this in turn allows CSVData to accept arbitrary sized tuples,
by rendering them into CSVLine
Whenever a class defines a single-arg templated constructor,
there is danger to shadow the auto-generated copy operations,
leading to insidious failures.
Some months ago, I did the ''obvious'' and added a tiny helper,
allowing to mask out the dangerous case when the ''single argument''
is actually the class itself (meaning, it is a copy invocation and
not meant to go through this templated ctor...
As this already turned out as tremendously helpful, I now extended
this helper to also cover cases where the problematic constructor
accepts variadic arguments, which is quite common with builder-helpers
The intention is to create a library of convenient building blocks;
providing a visualisation should be as simple as invoking a free function
with CSV data, yet with the ability to tweak some lables or display
variations if desired.
This can be achieved by..
* having a series of ready-made standard visualisations
* expose a function call for each, accepting a data-context builder
* provide secondary convenience shortcuts, which add some of the expected bindings
* notably a shortcut is provided to take the data as CSV-string
* augmented by a wrapper/builder to allow defining data points inline
Deliberately keep it unstructured and add dedicated functions
for each new emerging use case; hopefully some commen usage scheme
will emerge over time.
* Data is to be handed in as an iterator over CSV-strings.
* will have to find out about additional parametrisation on a case-by-case base
A minimalist `TextTemplate` engine is available for in-project use.
* supports only the bare minimum of features (no programming language)
* substitution of `${placeholder}` by key-name data access
* conditional section `${if key}...${end if}`
* iteration over a data sequence
* other then most solutions available as library,
this implementation does **not require** a specific data type,
nor does it invent a dynamic object system or JSON backend;
rather, a generic ''Data Source Adapter'' is used, which can
be specialised to access any kind of ''structured data''
* the following `DataSource` specialisations are provided
* `std::map<string,string>`
* Lumiera »External Tree Description« (based on `GenNode`)
* a string-based spec for testing
This extension is required to use GenNode as data source for text-template instantiation.
I am aware that such a function could counter the design intent for GenNode,
because it could be (ab)used to "just get the damn value" and then
parse back the results...
...turns out challenging, since our intention here
is borderline to the intended design of the Lumiera ETD.
It ''should work'' though, when combined with a Variant-visitor...
Document existing data binding logic and investigate in detail
what must be done to enable a similar binding backed by Lumiera's ETD structures.
This analysis highlights some tricky aspects, which can be accommodated by
slight adjustments and generalisations in the `TextTemplate` implementation
* `GenNode` is not structured string data, rather binary data
* thus exposing a std::string_view is not adequate, requiring to
pick up the result type from the actual data binding
* moreover, to allow for arbitrary nested scopes, a back-pointer
to the parent scope must be maintained, which requires stable memory locations.
This can best be solved within the InstanceCore itself, which manages
the actual hierarchy of data source references.
* the existing code happens already to fulfil this requirement, but
for sake of clarity, handling of such a nested scope is now extracted
into a dedicated operation, to highlight the guaranteed memory layout.
...hoped to keep it simple, but this is inevitable, since we
want to provide a CSV list as value within a list of key=value
bindings, and all packaged into a simple string for easy testing.
Thus the parsing RegExp just needs two branches for simple and quoted vals
...implemented by simply parsing the string into key=value pairs,
which are then stored into a shared map. The actual data binding
implementation can thus be inherited from the existing Map-binding
While they were detected just fine, thy were passed-through
unaltered, which subverts the purpose of such an escape,
which is to allow for the tag syntax to be present in the
processed, substituted document (e.g. when generating a
shell script)
thus `\${escaped}` becomes `${escaped}`
...turns out the ''pipeline design'' is not a good fit for the
Action compilation, since the compiler needs to refer to previous Actions;
better to let the compiler ''build'' the `ActionSeq`
...implemented as »custom processing layer« within a
demand-driven parsing pipeline, with the ability to
inject additional Action-tokens to represent the intermittent
constant text between tags; special handling to expose one
constant postfix after the last active tag.
MatchSeq was imported recently from the Yoshimi-testsuite,
as supporting helper for the CSV table component.
Actually this is just a thin wrapper on top of std::regex_iterator,
which in turn has properties and behaviour very similar to Lumiera's
»Forward Iterator« concept (in fact, it was a source of inspiration to
generalise such a pattern).
So this is an obvious round out and cleanup, as it requires just some
minor additions and adjustments to allow processing a sequence of matches
through a for-loop or some elaborate pipelining setup.
The way I've written this helper template, as a byproduct
it is also possible to maintain the back-refrence to the container
through a smart-ptr. In this case, the iterator-handle also manages
the ownership automatically.
...mostly we want the usual convenient handling pattern for iterators,
but with the proviso actually to perform an access by subscript,
and the ability to re-set to another current index
* establish the feature set to provide
* choose scheme for runtime representation
* break down analysis to individual parsing and execution steps
* conclude which actions to conduct and the necessary data
* derive the abstract binding API required
Conducted an extended investigation regarding text templating
and the library solutions available and still maintained today.
The conclusion is
* there are some mature and widely used solutions available for C++
* all of these are considered a mismatch for the task at hand,
which is to generate Gnuplot scripts for test data visualisation
Points of contention
* all solutions offer a massive feature set, oriented towards web content generation
* all solutions provide their own structured data type or custom property-tree framework
**Decision** 🠲 better to write a minimalistic templating engine from scratch rather
In the Lumiera code base, we use C-String constants as unique error-IDs.
Basically this allows to create new unique error IDs anywhere in the code.
However, definition of such IDs in arbitrary namespaces tends to create
slight confusion and ambiguities, while maintaining the proper use statements
requires some manual work.
Thus I introduce a new **standard scheme**
* Error-IDs for widespread use shall be defined _exclusively_ into `namespace lumiera::error`
* The shorthand-Macro `LERR_()` can now be used to simplify inclusion and referral
* (for local or single-usage errors, a local or even hidden definition is OK)
reduce footprint of lib/util.hpp
(Note: it is not possible to forward-declare std::string here)
define the shorthand "cStr()" in lib/symbol.hpp
reorder relevant includes to ensure std::hash is "hijacked" first
showDecimal -> decimal10 (maximal precision to survive round-trip through decimal representation=
showComplete -> max_decimal10 (enough decimal places to capture each possible distinct floating-point value)
Use these new functions to rewrite the format4csv() helper
...this uncovered one inconsistency: when directly adding values
into one of the embedded data vectors, the inconsistent size
was allowed to persist even when adding / removing lines.
This is in contradiction to the behavior for the CSV dump,
which uses index positions from the front of all vectors uniformely.
Thus changed the behaviour of adding a new row, so that it now
caps all vectors to a common size
also added function to clear the table
verify also that clean-up happens in case of exceptions thrown;
as an aside, add Macro to check for ''any'' exception and match
on something in the message (as opposed to just a Lumiera Exception)
...using the same method for sake of uniformity
Also move the permissions helpers to the file.hpp support functions
and setup a separate unit test for these
Inspired by https://stackoverflow.com/a/58454949
Verified behaviour of fs::create_directory
--> it returns true only if it ''indeed could create'' a new directory
--> it returns false if the directory exists already
--> it throws when some other obstacle shows up
As an aside: the Header include/limits.h could be cleaned up,
and it is used solely from C++ code, thus could be typed, namespaced etc.
Since this is a much more complicated topic,
for now I decided to establish two instances through global variables:
* a sequence seeded with a fixed starting value
* another sequence seeded from a true entropy source
What we actually need however is some kind of execution framework
to define points of random-seeding and to capture seed values for
reproducible tests.
Relying on random numbers for verification and measurements is known to be problematic.
At some point we are bound to control the seed values -- and in the actual
application usage we want to record sequence seeding in the event log.
Some initial thoughts regarding this intricate topic.
* a low-ceremony drop-in replacement for rand() is required
* we want the ability to pick-up and control each and every usage eventually
* however, some usages explicitly require true randomness
* the ability to use separate streams of random-number generation is desirable
Yesterday I decided to include some facilities I have written in 2022
for the Yoshimi-Testsuite. The intention is to use these as-is, and just
to adapt them stylistically to the Lumiera code base.
However — at least some basic documentation in the form of
very basic unit-tests can be considered »acceptance criteria«
Basically users are free to place the measurement calls to their liking.
This implies that bracketed measurement intervals can be defined overlapping
even within a single thread, thereby accounting the overlapping time interval
several times. However, for the time spent per thread, only actual thread
activity should be counted, disregarding overlaps. Thus introduce a
new aggregate, ''active time'', which is the sum of all thread times.
As an aside, do not need explicit randomness for the simple two-thread
test case — timings are random anyway...
+ bugfix for out-of-bounds access
...since we've established already an integration over the event timeline,
it is just one simple further step to determine the concurrency level
on each individual segment of the timeline. Based on this attribution
- the averaged concurrenty within the observation range can be computed as weighted mean
- moreover we can account for the precise cumulated time spent at each concurrency level
...using a simplistic allocation of next-slot based on initialisation
of a thread_local storage. This implies that this helper can not be
reset or reused, and that there can not be multiple or long-lived instances.
Keep-it-simple for now...
...to sort out the interpretation of measurement results,
the actual duration and concurrency of ComputationLoad invocations
should be recorded, allowing to draw conclusions regarding the
Scheduler's performance as opposed to further system and thread
management effects due to concurrent operation under pressure.
...so IterExplorer got yet another processing layer,
which uses the grouping mechanics developed yesterday,
but is freely configurable through λ-Functions.
At actual usage sit in TestChainLoad, now only the actual
aggregation computation must be supplied, and follow-up computations
can now be chained up easily as further transformation layers.
...during development of the Chain-Load, it became clear that we'll often
need a collection of small trees rather than one huge graph. Thus a rule
for pruning nodes and finishing graphs was added. This has the consequence
that there might now be several exit nodes scattered all over the graph;
we still want one single global hash value to verify computations,
thus those exit hashes must now be picked up from the nodes and
combined into a single value.
All existing hash values hard coded into tests must be updated
- use a dedicated context "dropped off" the TestChainLoad instance
- encode the node-idx into the InvocationInstanceID
- build an invocation- and a planning-job-functor
- let planning progress over an lib::UninitialisedStorage array
- plant the ActivityTerm instances into that array as Scheduling progresses
... special rule to generate a fixed expansion on each seed
... consecutive reductions join everything back into one chain
... can counterbalance expansions and reductions
...as it turns out, the solution embraced first was the cleanest way
to handle dynamic configuration of parameters; just it did not work
at that time, due to the reference binding problem in the Lambdas.
Meanwhile, the latter has been resolved by relying on the LazyInit
mechanism. Thus it is now possible to abandon the manipulation by
side effect and rather require the dynamic rule to return a
''pristine instance''.
With these adjustments, it is now possible to install a rule
which expands only for some kinds of nodes; this is used here
to crate a starting point for a **reduction rule** to kick in.
It seams indicated to verify the generated connectivity
and the hash calculation and recalculation explicitly
at least for one example topology; choosing a topology
comprised of several sub-graphs, to also verify the
propagation of seed values to further start-nodes.
In order to avoid addressing nodes directly by index number,
those sub-graphs can be processed by ''grouping of nodes'';
all parts are congruent because topology is determined by
the node hashes and thus a regular pattern can be exploited.
To allow for easy processing of groups, I have developed a
simplistic grouping device within the IterExplorer framework.
up to now, random values were completely determined by the
Node's hash, leading to completely symmetrical topology.
This is fine, but sometimes additional randomness is desirable,
while still keeping everything deterministic; the obvious solution
is to make the results optionally dependent on the invocation order,
which is simply to achieve with an additional state field. After some
tinkering, I decided to use the most simplistic solution, which is
just a multiplication with the state.
...so this was yet another digression, caused by the desire
somehow to salvage this problematic component design. Using a
DSL token fluently, while internally maintaining a complex and
totally open function based configuration is a bit of a stretch.
...this is a more realistic demo example, which mimics
some of the patterns present in RandomDraw. The test also
uses lambdas linking to the actual storage location, so that
the invocation would crash on a copy; LazyInit was invented
to safeguard against this, while still allowing leeway
during the initialisation phase in a DSL.
- Helper function to find out of two objects are located
"close to each other" -- which can be used as heuristics
to distinguish heap vs. stack storage
- further investigation shows that libstdc++ applies the
small-object optimisation for functor up to »two slots«
in size -- but only if the copy-ctor is trivial. Thus
a lambda capturing a shared_ptr by value will *always*
be maintained in heap storage (and LazyInit must be
redesigned accordingly)...
- the verify_inlineStorage() unit test will now trigger
if some implementation does not apply small-object optimisation
under these minimal assumptions
...which is crucial for the solution pursued at the moment;
std::function is known to apply a small-object optimisation,
yet unfortunately there are no guarantees by the C++ standard
(it is only mandated that std::function handles a bare function
pointer without overhead)
Other people have investigated that behaviour already,
indicating that at least one additional »slot« of data
can be handled with embedded storage in all known implementations
(while libstdc++ seemingly imposes the strongest limitations)
https://stackoverflow.com/a/77202545/444796
This experiment in the unit-test shows that for my setup
(libstdc++ and GCC-8) only a lambda capturing a single pointer
is handled entirely embedded into the std::function; already
a lambda capturing a shared-ptr leads to overflow into heap
the RandomDraw rules developed last days are meant to be used
with user-provided λ-adapters; employing these in a context
of a DSL runs danger of producing dangling references.
Attempting to resolve this fundamental problem through
late-initialisation, and then locking the component into
a fixed memory location prior to actual usage. Driven by
the goal of a self-contained component, some advanced
trickery is required -- which again indicates better
to write a library component with adequate test coverage.
...now using the reworked partial-application helper...
...bind to *this and then recursively re-invoke the adaptation process
...need also to copy-capture the previously existing mapping-function
first test seems to work now
Investigation in test setup reveals that the intended solution
for dynamic configuration of the RandomDraw can not possibly work.
The reason is: the processing function binds back into the object instance.
This implies that RandomDraw must be *non-copyable*.
So we have to go full circle.
We need a way to pass the current instance to the configuration function.
And the most obvious and clear way would be to pass it as function argument.
Which however requires to *partially apply* this function.
So -- again -- we have to resort to one of the functor utilities
written several years ago; and while doing so, we must modernise
these tools further, to support perfect forwarding and binding
of reference arguments.
- strive at complete branch coverage for the mapping function
- decide that the neutral value can deliberately lie outside
the value range, in which case the probability setting
controls the number of _value_ result incidents vs
neutral value result incidents.
- introduce a third path to define this case clearly
- implement the range setting Builder-API functions
- absorb boundrary and illegal cases
For sake of simplicity, since this whole exercise is a byproduct,
the mapping calculations are done in doubles. To get even distribution
of values and a good randomisation, it is thus necessary to break
down the size_t hash value in a first step (size_t can be 64bit
and random numbers would be subject to rounding errors otherwise)
The choice of this quantiser is tricky; it must be a power of two
to guarantee even distribution, and if chosen to close to the grid
of the result values, with lower probabilities we'd fail to cover
some of the possible result values. If chosen to large, then
of course we'd run danger of producing correlated numbers on
consecutive picks.
Attempting to use 4 bits of headroom above the log-2 of the
required value range. For example, 10-step values would use
a quantiser of 128, which looks like a good compromise.
The following tests will show how good this choice holds up.
The first step was to allow setting a minimum value,
which in theory could also be negative (at no point is the
code actually limited to unsigned values; this is rather
the default in practice).
But reconsidering this extensions, then you'd also want
the "neutral value" to be handled properly. Within context,
this means that the *probability* controls when values other
than the neutral value are produced; especially with p = 1.0
the neutral value shall not be produced at all
...since the Policy class now defines the function signature,
we can no longer assume that "input" is size_t. Rather, all
invocations must rely on the generic adaptaion scheme.
Getting this correct turns out rather tricky again;
best to rely on a generic function-composition.
Indeed I programmed such a helper several years ago,
with the caveat that at that time we used C++03 and
could not perfect-forward arguments. Today this problem
can be solved much more succinct using generic Lambdas.
to define this as a generic library component,
any reference to the actual data source moust be extracted
from the body of the implementation and supplied later
at usage site. In the actual case at hand the source
for randomness would be the node hash, and that is
absolutely an internal implementation detail.
The idea is to use some source of randomness to pick a
limited parameter value with controllable probability.
While the core of the implementation is nothing more
than some simple numeric adjustments, these turn out
to be rather intricate and obscure; the desire to
package these technicalities into a component
however necessitates to make invocations
at usage site self explanatory.
...using a pre-established example as starting point
It seems that building up this kind of generator code
from a set of free functions in a secluded namespace
is the way most suitable to the nature of the C++ language
Use a simple destructor-trick to set up a concise notation
for temporarily manipulating a value for testing.
The manipulation will automatically be undone
when leaving scope
...to bring it more in line with all the other calls dealing with Activity*
...allows also to harmonise the ActivityLang::dispatchChain()
...and to compose the calls in Scheduler directly
NOTE: there is a twist: our string-formatting helper did not render
custom string conversions for objects passed as pointer. This was a
long standing problem, caused by ambiguous templates overloads;
now I've attempted to solve it one level more down, in util::StringConv.
This solution may turn out brittle, since we need to exclude any direct
string conversion, most notably the ones for C-Strings (const char*)
In case this solution turns out unsustainable, please feel free
to revert this API change, and return to passing Activity& in λ-post,
because in the end this is cosmetics.
As follow-up to the rework of thread-handling, likewise also
the implementation base for locking was switched over from direct
usage of POSIX primitives to the portable wrappers available in
the C++ standard library. All usages have been reviewed and
modernised to prefer λ-functions where possible.
With this series of changes, the old threadpool implementation
and a lot of further low-level support facilities are not used
any more and can be dismantled. Due to the integration efforts
spurred by the »Playback Vertical Slice«, several questions of
architecture could be decided over the last months. The design
of the Scheduler and Engine turned out different than previously
anticipated; notably the Scheduler now covers a wider array of
functionality, including some asynchronous messaging. This has
ramifications for the organisation of work tasks and threads,
and leads to a more deterministic memory management. Resource
management will be done on a higher level, partially superseding
some of the concepts from the early phase of the Lumiera project.
This is Step-2 : change the API towards application
Notably all invocation variants to support member functions
or a reference to bool flags are retracted, since today a
λ-binding directly at usage site tends to be more readable.
The function names are harmonised with the C++ standard and
emergency shutdown in the Subsystem-Runner is rationalised.
The old thread-wrapper test is repurposed to demonstrate
the effectiveness of monitor based locking.
After the fundamental switch from POSIX to the C++14 wrappers
the existing implementation of the Monitor can now be drastically condensed,
removing several layers of indirection. Moreover, all signatures
shall be changed to blend in with the names and patterns established
by the C++ standard.
This is Step-1 : consolidate the Implementation.
(to ensure correctness, the existing API towards application code was retained)
While not directly related to the thread handling framework,
it seems indicated to clean-up this part of the application alongside.
For »everyday« locking concerns, an Object Monitor abstraction was built
several years ago and together with the thread-wrapper, both at that time
based on direct usage of POSIX. This changeset does a mere literal
replacement of the POSIX calls with the corresponding C++ wrappers
on the lowest level. The resulting code is needlessly indirect, yet
at API-level this change is totally a drop-in replacment.
This, and the GUI thread prompted an further round of
design extensions and rework of the thread-wrapper.
Especially there is now support for self-managed threads,
which can be launched and operate completely detached from the
context used to start them. This resolves an occasional SEGFAULT
at shutdown. An alternative (admittedly much simpler) solution
would have been to create a fixed context in a static global
variable and to attach a regular thread wrapper from there,
managed through unique_ptr.
It seems obvious that the new solution is preferable,
since all the tricky technicalities are encapsulated now.
Add a complete demonstration for a setup akin to what we use
for the Session thread: a threaded component which manages itself
but also exposes an external interface, which is opened/closed alongside
...extract and improve the tuple-rewriting function
...improve instance tracking test dummy objects
...complete test coverage and verify proper memory handling
After quite some detours, with this take I'm finally able to
provide a stringent design to embody all the variants of thread start
encountered in practice in the Lumiera code base.
Especially the *self-managed* thread is now represented as a special-case
of a lifecycle-hook, and can be embodied into a builder front-end,
able to work with any client-provided thread-wrapper subclass.
to cover the identified use-cases a wide variety of functors
must be accepted and adapted appropriately. A special twist arises
from the fact that the complete thread-wrapper component stack works
without RTTI; a derived class can not access the thread-wrapper internals
while the policy component to handle those hooks can not directly downcast
to some derived user provided class. But obviously at usage site it
can be expected to access both realms from such a callback.
The solution is to detect the argument type of the given functor
and to build a two step path for a safe static cast.
...after resolving the fundamental design problems,
a policy mix-in can be defined now for a thread that deletes
its own wrapper at the end of the thread-function.
Such a setup would allow for »fire-and-forget« threads, but with
wrapper and ensuring safe allocations. The prominent use case
for such a setup would be the GUI-Thread.
Concept study of the intended solution successful.
Can now transparently embed any conceivable functor
and an arbitrary argument sequence into a launcher-λ
Materialising into a std::tuple<decay_t<TYPES...>> did the trick.
Considering a solution to shift the actual launch of the new thread
from the initialiser list into the ctor body, to circumvent the possible
"undefined behaviour". This would also be prerequisite for defining
a self-managed variant of the thread-wrapper.
Alternative / Plan.B would be to abandon the idea of a self-contained
"thread" building block, instead relying on precise setup in the usage
context -- however, not willing to yield yet, since that would be exactly
what I wanted to avoid: having technicalities of thread start, argument
handover and failure detection intermingled with the business code.
On a close look, the wrapper design as pursued here
turns out to be prone to insidious data race problems.
This was true also for the existing solution, but becomes
more clear due to the precise definitions from the C++ standard.
This is a confusing situation, because these races typically do not
materialise in practice; due to the latency of the OS scheduler the
new thread starts invoking user code at least 100µs after the Wrapper
object is fully constructed (typically more like 500µs, which is a lot)
The standard case (lib::Thread) in its current form is correct, but borderline
to undefined behaviour, and any initialisation of members in a derived class
would be off limits (the thread-wrapper should not be used as baseclass,
rather as member)
...while reworking the application code, it became clear that
actually there are two further quite distinct variants of usage.
And while these could be implemented with some trickery based on
the Thread-wrapper defined thus far, it seems prudent better to
establish a safely confined explicit setup for these cases:
- a fire-and-forget-thread, which manages its own memory autonomously
- a thread with explicit lifecycle, with detectable not-running state
...these were already written envisionaging he new API,
so it's more or less a drop-in replacement.
- cant use vector anymore, since thread objects are move-only
- use ScopedCollection instead, which also has the benefit of
allocating the requires space up-front. Allow to deduce the
type parameter of the placed elements
... which became apparent after switching to the new Thread-wrapper implementation
... the reason is a bug in the Thread-Monitor (which will also be reworked soon)
While seemingly subtle, this is a ''deep change.''
Up to now, the project attempted to maintain two mutually disjoint
systems of error reporting: C-style error flags and C++ exceptions.
Most notably, an attempt was made to keep both error states synced.
During the recent integration efforts, this increasingly turned out
as an obstacle and source for insidious problems (like deadlocks).
As a resolve, hereby the relation of both systems is **clarified**:
* C-style error flags shall only be set and used by C code henceforth
* C++ exceptions can (optionally) be thrown by retrieving the C-style error code
* but the opposite is now ''discontinued'' : Exceptions ''do not set'' the error flag anymore
...this function was also ported to the new wrapper,
and can be verified now in a much more succinct way.
''This completes porting of the thread-wrapper''
Since the decision was taken to retain support for this special feature,
and even extend it to allow passing values, the additional functionality
should be documented in the test. Doing so also highlighted subtle problems
with argument binding.
Now the ThreadWrapper_test offers both
- a really simple usage example
- a comprehensive test to verify that actually the
thread-function is invoked the expected number of times
and that this invocations must have been parallelised
- it is not directly possible to provide a variadic join(args...),
due to overload resolution ambiguities
- as a remedy, simplify the invocation of stringify() for the typical cases,
and provide some frequently used shortcuts
A common usage pattern is to derive from lib::Thread
and then implement the actual thread function as a member function
of this special-Thread-object (possibly also involving other data members)
Provide a simplified invocation for this special case,
also generating the thread-id automatically from the arguments
after all this groundwork, implementing the invocation,
capturing and hand-over of results is simple, and the
thread-wrapper classes became fairly understandable.
This relieves the Thread policy from a lot of technicalities,
while also creating a generally useful tool: the ability to invoke
/anything callable/ (thanks to std::invoke) in a fail-safe way and
transform the exception into an Either type
on second thought, the ability to transport an exception still seems
worthwhile, and can be achieved by some rearrangements in the design.
As preparation, reorganise the design of the Either-wrapper (lib::Result)
- relocate some code into a dedicated translation unit to reduce #includes
- actually set the thread-ID (the old implementation had only a TODO at that point)
While it would be straight forward from an implementation POV
to just expose both variants on the API (as the C++ standard does),
it seems prudent to enforce the distinction, and to highlight the
auto-detaching behaviour as the preferred standard case.
Creating worker threads just for one computation and joining the results
seemed like a good idea 30 years ago; today we prefer Futures or asynchronous
messaging to achieve similar results in a robust and performant way.
ThreadJoinable can come in handy however for writing unit tests, were
the controlling master thread has to wait prior to perform verification.
So the old design seems well advised in this respect and will be retained
- cut the ties to the old POSIX-based custom threadpool framework
- remove operations deemed no longer necessary
- sync() obsoleted by the new SyncBarrier
- support anything std::invoke supports
...which is the technique used in the existing Threadpool framwork.
As expected, such a solution is significantly slower than the new
atomics-based implementation. Yet how much slower is still striking.
Timing measurements in concurrent usage situation.
Observed delay is in the order of magnitude of known scheduling leeway;
assuming thus no relevant overhead related to implementation technique
Over time, a collection of microbenchmark helper functions was
extracted from occasional use -- including a variant to perform
parallelised microbenchmarks. While not used beyond sporadic experiments yet,
this framework seems a perfect fit for measuring the SyncBarrier performance.
There is only one catch:
- it uses the old Threadpool + POSIX thread support
- these require the Threadpool service to be started...
- which in turn prohibits using them for libary tests
And last but not least: this setup already requires a barrier.
==> switch the existing microbenchmark setup to c++17 threads preliminarily
(until the thread-wrapper has been reworked).
==> also introduce the new SyncBarrier here immediately
==> use this as a validation test of the setup + SyncBarrier
Using the same building blocks, this operation can be generalised even more,
leading to a much cleaner implementation (also with better type deduction).
The feature actually used here, namely summing up all values,
can then be provided as a convenience shortcut, filling in std::plus
as a default reduction operator.
...first used as part of the test harness;
seemingly this is a generic and generally useful shortcut,
similar to algorithm::reduce (or some kind of fold-left operation)
Intended as replacement for the Mutex/ConditionVar based barrier
built into the exiting Lumiera thread handling framework and used
to ensure safe hand-over of a bound functor into the starting new
thread. The standard requires a comparable guarantee for the C++17
concurrency framework, expressed as a "synchronizes_with" assertion
along the lines of the Atomics framework.
While in most cases dedicated synchronisation is thus not required
anymore when swtiching to C++17, some special extended use cases
remain to be addressed, where the complete initialisation of
further support framework must be ensured.
With C++20 this would be easy to achieve with a std::latch, so we
need a simple workaround for the time being. After consideration of
the typical use case, I am aiming at a middle ground in terms of
performance, by using a yield-wait until satisfying the latch condition.
The investigation for #1279 leads to the following conclusions
- the features and the design of our custom thread-wrapper
almost entirely matches the design chosen meanwhile by the C++ committee
- the implementation provided by the standard library however uses
modern techniques (especially Atomics) and is more precisely worked out
than our custom implementation was.
- we do not need an *active* threadpool with work-assignment,
rather we'll use *active* workers and a *passive* pool,
which was easy to implement based on C++17 features
==> decision to drop our POSIX based custom implementation
and to retrofit the Thread-wrapper as a drop-in replacement
+++ start this refactoring by moving code into the Library
+++ create a copy of the Threadwrapper-code to build and test
the refactorings while the application itself still uses
existing code, until the transition is complete
requires to supplement EventLog matching primitives
to pick and verify a specific positional argument.
Moreover, it is more or less arbitrary which job invocation parameters
are unpacked and exposed for verification; we'll have to see what is
actually required for writing tests...
Testcase (detect function invocation) passes now as expected
Some Library / Framework changes
- rename event-log-test.cpp
- allow the ExpectString also to work with concatenated expectation strings
Remark: there was a warning in the comment in event-log.hpp,
pointing out that negative assertions are shallow.
However, after the rework in 9/2018 (commit: d923138d1)
...this should no longer be true, since we perform proper backtracking,
leading to an exhaustive search.
...turns out this is entirely generic and not tied to the context
within ActivityDetector, where it was first introduced to build a
mock functor to log all invocations.
Basically this meta-function generates a new instantiation of the
template X, using the variadic argument pack from template U<ARGS...>
Library: add "obvious" utility to the IterExplorer, allowing to
materialise all contents of the Pipeline into a container
...use this to take a snapshot of all currently active Extent addresses
- the idea is to use slot-0 in each extent for administrative metadata
- to that end, a specialised GATE-Activity is placed into slot-0
- decision to use the next-pointer for managing the next free slot
- thus we need the help of the underlying ExtentFamily for navigating Extents
Decision to refrain from any attempt to "fix" excessive memory usage,
caused by Epochs still blocked by pending IO operations. Rather, we
assume the engine uses sane parametrisation (possibly with dynamic adjustment)
Yet still there will be some safety limit, but when exceeding this limit,
the allocator will just throw, thereby killing the playback/render process
The second design from 2017, based on a pipeline builder,
is now renamed `TreeExplorer` ⟼ `IterExplorer` and uses
the memorable entrance point `lib::explore(<seq>)`
✔
after completing the recent clean-up and refactoring work,
the monad based framework for recursive tree expansion
can be abandoned and retracted.
This approach from functional programming leads to code,
which is ''cool to write'' yet ''hard to understand.''
A second design attempt was based on the pipeline and decorator pattern
and integrates the monadic expansion as a special case, used here to
discover the prerequisites for a render job. This turned out to be
more effective and prolific and became standard for several exploring
and backtracking algorithms in Lumiera.
...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
- had to fix a logical inconsistency in the underlying Expander implementation
in TreeExplorer: the source-pipeline was pulled in advance on expansion,
in order to "consume" the expanded element immediately; now we retain
this element (actually inaccessible) until all of the immediate
children are consumed; thus the (visible) state of the PipeFrameTick
stays at the frame number corresponding to the top-level frame Job,
while possibly expanding a complete tree of flexible prerequisites
This test now gives a nice visualisation of the interconnected states
in the Job-Planning pipeline. This can be quite complex, yet I still think
that this semi-functional approach with a stateful pipeline and expand functors
is the cleanest way to handle this while encapsulating all details
...introduced in preparation for building the Dispatcher pipeline,
which at its core means to iterate over a sequence of frame positions;
thus we need a way to stop rendering at a predetermined point...
...which uncovers further deeply nested problems,
especially when referring to non-copyable types.
Thus need to construct a common type that can be used
both to refer to the source elements and the expanded elements,
and use this common type as result type and also attempt to
produce better diagnostic messages on type mismatch....
...the improved const correctness on STL iterators uncovered another
latent problem with out diagnositc format helper, which provide
consistently rounded float and double output, but failed to take
CV-qualifiaction into account
This is a subtle and far reaching fix, which hopefully removes
a roadblock regarding a Dispatcher pipeline: Our type rebinding
template used to pick up nested type definitions, especially
'value_type' and 'reference' from iterators and containers,
took an overly simplistic approach, which was then fixed
at various places driven by individual problems.
Now:
- value_type is conceptually the "thing" exposed by the iterator
- and pointers are treated as simple values, and no longer linked
to their pointee type; rather we handle the twist regarding
STL const_iterator direcly (it defines a non const value_type,
which is sensible from the STL point of view, but breaks our
generic iterator wrapping mechanism)
- only the parts actually touched by the algo will be re-allocated
- when a segment is split, the clone copies carry on all data
Library: add function to check for a bare address (without type info)
...this is something I should have done since YEARS, really...
Whenever working with symbolically represented data, tests
typically involve checking *hundreds* of expected results,
and thus it can be really hard to find out where the
failure actually happens; it is better for readability
to have the expected result string immediately in the
test code; now this expected result can be marked
with a user-defined literal, and then on mismatch
the expected and the real value will be printed.
There are 12 distinct cases regarding the orientation of two intervals;
The Segmentation::splitSplice() operation shall insert a new Segment
and adjust / truncate / expand / split / delete existing segments
such as to retain the *Invariant* (seamless segmentation covering
the complete time axis)
- how to pass-in a specification given as GenNode
- now this might be translated into a MockJobTicket allocated in the MockSegmentation
Unimplemented: actually build the Segment with suitable start/end time
Looks like we'll actually retain and use this low-level solution
in cases where we just can not afford heap allocations but need
to keep polymorphic objects close to one another in memory.
Since single linked lists are filled by prepending, it is rather
common to need the reversed order of elements for traversal,
which can be achieved in linear time.
And while we're here, we can modernise the templated emplacement functions
- 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
...in a similar vein as done for the product calculation.
In this case, we need to check the dimensions carefully and pick
the best calculation path, but as long as the overall result can
be represented, it should be possible to carry out the calculation
with fractional values, albeit introducing a small error.
As a follow-up, I have now also refactored the re-quantisation
functions, to be usable for general requantisation to another grid,
and I used these to replace the *naive* implementation of the
conversion FSecs -> µ-Grid, which caused a lot of integer-wrap-around
However, while the test now works basically without glitch or wrap,
the window position is still numerically of by 1e-6, which becomes
quite noticeably here due to the large overall span used for the test.
- detailed documentation of known problematic behaviour
when working with rational fractions
- demonstrate the heuristic predicate to detect dangerous numbers
- add extensive coverage and microbenchmarks for the integer-logarithm
implementation, based on an example on Stackoverflow. Surprising result:
The std::ilog(double) function is of comparable speed, at least for
GCC-8 on Debian-Buster.
The header "format-cout.hpp" offers a convenience function
to print pretty much any object or data in human readable form.
However, the formatter for pointers used within this framework
switched std::cout into hexadecimal display of numbers and failed
to clean-up this state.
Since the "stickyness" of IOS stream manipulators is generally a problem,
we now provide a RAII helper to capture the previous stream state and
automatically restore it when leaving the scope.
Complete the investigation and turn the solution into a generic
mix-in-template, which can be used in flexible ways to support
this qualifier notation.
Moreover, recapitulate requirements for the ElementBoxWidget
- 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
...this extension was spurred by the previeous refactoring.
Since 'emplace' now clearly denotes an operation to move-embed an existing object,
we could as well offer a separate 'create' API, which would take forwarding
arguments as usual and just delegates to the placement-new operation 'create'
already available in the InPlaceBuffer class.
Such would be a convenience shortcut and is not strictly necessary,
since move-construction is typically optimised away; yet it would also
allow to support strictly non-copyable payload types.
This refactoring also highlights a fuzziness in the existing design,
where we just passed the interface type, while being sloppy about the
DEFAULT type. In fact this *is* relevant, since any kind of construction
might fail, necessitating to default-construct a placeholder, since
InPlaceBuffer was intended for zero-overhead usage and thus has in itself
no means to know about the state of its buffer's contents. Thus the
only sane contract is that there is always a valid object emplaced
into the buffer, which in turn forces us to provide a loophole for
class hierarchies with an abstract base class -- in such a case the
user has to provide a fallback type explicitly.
...for the operation on a PlantingHandle, which allows
to implant a sub type instance into the opaque buffer.
* "create" should be used for a constructor invocation
* "emplace" takes an existing object and move-constructs
...in an attempt to clarify why numerous cross links are not generated.
In the end, this attempt was not very successful, yet I could find some breadcrumbs...
- file comments generally seem to have a problem with auto link generation;
only fully qualified names seem to work reliably
- cross links to entities within a namespace do not work,
if the corresponding namespace is not documented in Doxygen
- documentation for entities within anonymous namespaces
must be explicitly enabled. Of course this makes only sense
for detailed documentation (but we do generate detailed
documentation here, including implementation notes)
- and the notorious problem: each file needs a valid @file comment
- the hierarchy of Markdown headings must be consistent within each
documentation section. This entails also to individual documented
entities. Basically, there must be a level-one heading (prefix "#"),
otherwise all headings will just disappear...
- sometimes the doc/devel/doxygen-warnings.txt gives further clues
...by relying on the newly implemented automatic standard binding
Looks like a significant improvement for me, now the actual bindings
only details aspects, which are related to the target, and no longer
such technicalitis like how to place a Child-Mutator into a buffer handle
After this long break during the "Covid Year 2020",
I pick this clean-up task as a means to fresh up my knowledge about the code base
The point to note is, when looking at all the existing diff bindings,
seemingly there is a lot of redundancy on some technical details,
which do not cary much meaining or relevance at the usage site:
- the most prominent case is binding to a collection of DiffMutables hold by smart-ptr
- all these objects expose an object identity (getID() function), which can be used as »Matcher«
- and all these objects can just delegate to the child's buildMutator() function
for entering a recursive mutation.
As it turned out, it is rather easy to extend the existing listener
for structural changes to detect also value assignments. Actually
it seems we'd need both flavours, so be it.
Yeah, C++17, finally!
...not totally sure if we want to go that route.
However, the noise reduction in terms of code size at call site looks compelling
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
"%broken" is not broken anymore, but renders a boolean,
and we configured the formatter not to complain on missing values.
Fortunately "%madness" is still broken ;-)
basically the solution was a bit too naive and assumed everything is similar to a vector.
It is not, and this leads to some insidious problems with std::map, which hereby
are resolved by introducing ContainerTraits
All of the existing "simple" tests for the »Diff Framework« are way to much low-level;
they might indeed be elementary, but not introductory and simple to grasp.
We need a very simplistic example to show off the idea of mutation by diff,
and this simple example can then be used to build further usage test cases.
My actual goal for #1206 to have such a very basic usage demonstration and then
to attach a listener to this setup, and verify it is actually triggered.
PS: the name "GenNodeBasic_test" is somewhat pathetic, this test covers a lot
of ground and is anything but "basic". GenNode in fact became a widely used
fundamental data structure within Lumiera, and -- admittedly -- the existing
implementation might be somewhat simplistic, while the whole concept as such
is demanding, and we should accept that as the state of affairs
For context: The »Advice System« was coined a long time ago, in 2010,
based on the vague impression that it might be useful for that kind of application
we are about to build here. And, as can be expected, none of the usage situations
envisioned at that time was brought to bear. Non the less, the facility came in
handy at times, precisely because it is cross-cutting and allows to pass
information without imposing any systematic relationship between the
communication partners.
And now we've got again such a situation.
The global style manager in the UI has to build a virtual CSS path,
which is needed by drawing code somewhere deep down, and we absolutely
do not want to pass a reference to the style manager over 20 recursive calls.
The alternatives would be
(1) to turn the style manager into a public service
(2) to have a static access function somewhere
(3) to use a global variable.
For rationale, (1) would be overblown, because we do not actually request
a service to do work for us, rather we need some global piece of information.
(2) would be equivalent to (1), just more confusing. And (3) is basically
what the Advice system does, with the added benefit of a clear-cut service
access point and a well defined lifecycle.
This changeset adds the ability to check if actual Advice has been published,
which allows us to invoke the (possibly expensive) GTK path building and
style context building code only once.
