Just looking at the average human microbiome, the actual humans probably rank lower than eyelash mites and cutibacterium acnes

delv-pls this plagiarized answer

Not technically plag because of attribution, but yeah

Gone. And now they get their 6 points back.

why do the async pipes not allow you to communicate between subprocesses asynchronously? e.g.: stackoverflow.com/questions/36657753/…

Design question. I have a class like this:

class Build:
    def __init__(self, plugins):
        self.plugins = plugins

    def run(self):
        for plugin in plugins:
            plugin.activate(self)

        ...  # do more stuff

And I can't decide how to handle the plugin activation. If I activate the plugins in the run method, then calling run() a 2nd time will lead to problems. But I also don't want to do it in __init__ because I don't want a constructor to have side effects

Should I add an internal boolean flag and only activate the plugins on the first call to run()?

So have __init__ establish a flag value plugins_activated initially false, and set it true when you activate them?

Formal answer: yes :)

Alright, thanks. Glad the answer wasn't "you're overthinking it, it doesn't matter" (:

Why wouldn't it? Even if activation is idempotent you'd be wasting time unnecessarily.

Well, I mean... if someone instantiates a Build and then doesn't call its run() method it's not me who's wasting time :P

No but you would be wasting time if they called it twice and you weren't using a flag.

FWIW it's exactly what I do with my library at work. I actually have multiple internal flags tracking several different states (e.g. someone has called .build() and .solve() on the Problem class). Even though I built the library myself and knew what problems multiple calls could create, I shot myself in the foot before having these flags in place

why not have the Problem class without a solve method but that has a build method that returns a BuiltProblem that doesn't have a build method, but does have a solve method that returns a SolvedProblem with neither?

or am I just too infected with that functional virus? ;-)

That may be a better design but I think it adds complexity. Especially when I was shooting for being able to fully serialize the Problem class and allow you to pick up a pre-solved Problem and add extra components before dispatching to the solver again

@Aran-Fey use @cache on run() :P

well it adds classes/types but it could remove some complexity of needing to check all relevant flags at various stages (build should check it wasn't built before and solve should check that it was)

Though, I suppose your approach could be adapted to my use case as well. I think it'd be more cognitive burden on me as the dev than it would be for the users

adding components to a SolvedProblem would then return a Problem I guess? so you are forced to do the build and solve again

@hugovdberg Sure, but all that is now fixed with self._is_built and self._is_solved that I can switch as needed in all use cases, so I save ~10 lines of code for now having 2 completely new objects

I do also have a Solution class that takes an instance of a solved Problem so that's where things get conceptually tricky with my approach, I can definitely see that

I'm not sure you're saving much lines if you need to check/set/reset the flags in all the right places, versus two lines class BuiltProblem: and class SolvedProblem that splits your current class at the right points ;-)

but I guess it also depends on how many attributes and methods of the Problem should be in the other states

or go entirely functional a make all methods just functions that transform to the various stages

You are definitely making me question my design, it's just the distinction of passing a Solution back to build the foundation of a new Problem that's now partly solved. It blurs the lines between what is a problem and a solution, and nobody needs to actually interact with the Solution class - the methods on the Problem will dispatch to the correct backend Solution class

So the interface on Problem is:

def get_solution(self):

        if not self._is_solved:
            raise ProblemError("Problem has not been solved!")

        result_parser = self.backends[self.config.solver]['solution'](self)

        return result_parser.get_solution_df()

So you don't want to solve lazily, then? It's valid to ask for a (currently non-existent) Solution?

I'm not sure what lazy means in this situation, but that's probably my failing. A Problem might pass through 10 different modules before it's in any fit state to be translated to a JSON payload to be dispatched to one of multiple different backend servers. In my case, I've made it so the user has to determine the point at which they're not going to add any more constraints

but this method could then just be added only to the SolvedProblem right? because then the only way to get the solution is to build and solve, which is a clear signal that there will be no more constraints added

The more we talk about this, the more I'm thinking it should be an instance of SolvedProblem, but then it would also require a route to translating back to a Problem in the case that you want to re-solve. Time-wise that's just not going to happen, but I'll keep it in mind for another similar library I'm about to start, so thanks for the input

.unsolve() obviously

At the time, I had a lot of questions about how to make switchable backends (the solvers that you can dispatch to take radically different JSON payloads, and also have different features), so I had to figure out how to handle that. Perhaps the design has not been given enough attention simply by making this switchable

@AndrasDeak Ah, but imagine you're solving a vehicle routing problem and you've already dispatched your fleet with parcels on board but new jobs come up. Alas, one cannot cast a summoning spell to get those parcels back that have already been dispatched, so a solved problem will have some features that have to cascade into a new problem

@roganjosh edition.cnn.com/2021/11/30/us/alabama-fedex-packages/index.html

That sounds like something the strategy pattern was distilled for ;-)

@AndrasDeak mmm. I'll keep it in mind. That might be a practical solution to my interface design

@roganjosh so you're not just adding constraints but building a new problem that has some of the old constraints and then some new constraints added?

In effect that. But a SolvedProblem that carries forward to become a new Problem will have certain constraints applied for you (i.e. if the previous solution determined that Parcel 1234 is on Vehicle B, that'll just magically happen when you call .solve() again with new parcels that weren't known the first time)

to me that sounds conceptually just as a different type of constraint, not just Parcel 1234 needs to go to Place X at Time T, but Parcel 1234 needs to Place X at Time T using Vehicle B

but I guess it would also depend on how your backend views constraints

That's exactly what it is. The Problem can have state that automagically cascades over from a previous Solution, hence why it becomes difficult to make a distinction between the two that will satisfy everyone's conceptual model

It should be noted that the existing setup works and nobody has complained about the interface. I think we could just be splitting hairs about API design but it's given me food for thought going forwards

haha I wasn't suggesting you should immediately do a rewrite :-) it was mostly that I'm always afraid I mess up checking or resetting those flags in all the right places

FWIW I haven't found it all that difficult, but then I also have all the solver servers running locally too to test. If I couldn't see that, then some of the weirdness of forgetting to flick the bool switches would be super-confusing in some cases because the mangled JSON will crash out in any number of obscure ways and the server responses would be without proper context

@roganjosh Sorry, life intruded.

By "lazy" I meant "solve when a client requests access to the solution." Making your code:

def get_solution(self):

        if not self._is_solved:
            self.backends[self.config.solver]['solution'] = self.solution(...)

        result_parser = self.backends[self.config.solver]['solution'](self)

        return result_parser.get_solution_df()

Also, there's no reason why the solution can't retain a reference to the problem it's a solution for, allowing it to be passed around (in-memory, anyway) as a simple object. Persisting them would mean multiple entities and use of foreign keys relationally. A doc store might do better :shrug:.

@roganjosh I'll be it's real fun when. truck breaks down along its route ...

Also, have you drawn any kind of state transition diagram for these objects? That can sometimes be helpful - especially in determining undefined states ...

And I'm afraid that's it from me, as I have a family lunch today. Rhubarb, all.

@AndrasDeak I'll pretend I didn't hear that :P

@holdenweb ahh, ok, I understand what you mean here. No, I absolutely want to avoid that because you could end up in a mixed state that you didn't expect (and it's shockingly easy to do when you're passing a single instance around tens of different files and forget to remove debug calls). A state transition diagram is an interesting suggestion; do you know of a good example to base it on?

Once again I'm stuck on the hardest part of a project: Choosing a name :(

It's related to exceptions, and exceptional is already taken by a module with, like, 4 functions. The nerve.

Yam, they even took the poor Harry Potter puns already!

What a world.

My module would only have 1 feature. It would be the best at what it does. Truly exceptional. Meanwhile, this amateur made a module with *four*(!) features. Seems more like a jack-of-all-trades than an exceptional master of one to me.

You could go old school with "xpct".

What's that? I can't find anything about it on google O.o

Well, that's how xcptional the name is.

Oh, I thought there's a story behind it. If it's just the txtspk version of "exception" then I'd rather not

"excepto-patronum" is still up for grabs, but my current favorite is "aberrant"

exceptschön

"anomaly" is also available. That one I don't have to look up in a dictionary...

@AndrasDeak Ja!

It still feels like magic to me that one can use non-ascii identifiers. What will they think of next?

It might be wise to call it exceptschon or exceptschoen anyway :P

@AndrasDeak Not bad!

@MisterMiyagi Hey, as far as I'm concerned that's a good thing. It's a synonym for "exceptional", it contains "err", and it teaches you a new word. That's a win-win-win.

It does have negative connotations at least in Hungarian

Along the lines of "deviant", but stronger

Hmm, seems to be the case in english as well. Maybe "aberrated" would be better?

> Characterized by defects, abnormality, or deviation from the usual, typical, or expected course.

That's fair for a module written by me.

Hi

@MisterMiyagi Don't: you can get some truly horrendous situations by being too cutesy with Unicode identifiers.

oh that's ghastly

@roganjosh 'Fraid I can't suggest any examples.from personal experience (I've always written problem-specific code since it hasn't been a frequent need) but it looks like State Machine might help.

@AndrasDeak Yeah, one of the downsides of being on the Nutshell team is you find out about the awful stuff.

@holdenweb Whoa! That's even more madness than I expected.

Isn't it just horrible the ratholes a simple wish to be inclusive can take you down?

I didn't read the whole mailing list thread, so I may be rehashing old ground here. Unicode identifiers could possibly give bad guys the ability to write code that looks like it does one thing, and instead does another thing. But can it cause problems even if there are no bad guys, only error-prone good guys?

Probably less so, but still yes?

I mean, less the security problems and more accidentally calling another method or something

The simplest example, "A good guy might try to create two variables that have different Unicode representations, but which normalize into a single identifier name" feels a bit far fetched

Help, what's the immutable dict wrapper in the stdlib called again? And what module is it in? I thought it was DictProxy, but I can't find it

"Oh weird, I did fiance\N{LATIN SMALL LETTER E}\N{COMBINING ACUTE ACCENT} = "Alice"; fiance\N{LATIN SMALL LETTER E WITH ACUTE} = "Carol", and now I can only access one of them. I cannot conceive why this would be the case!"

Oh, I found it, it's types.MappingProxyType

Perhaps this is an uncharitable example, because those variables will look identical in a sane IDE, so a sane developer will likely (and correctly) assume they're the same variable. But perhaps if you wrote ᵖoobar = 1; poobar = 2, they look different enough that the reader would guess they're distinct.

I suspect that these "code points that look quite different but normalize to the same string" pairs are pretty rare if you just stick to characters used in modern written languages. On the other hand, the world is big and my experience is small, so I am prepared to be swiftly proven wrong

"Turns out the kanji for 'print diagnostic information' and 'create backup' both normalize to the kanji for 'erase hard drive and catch fire'. It's actually perfectly logical if you know about the history of ancient Chinese oracular bone scribing"

Wait, accented letters feel like something "pretty rare if you just stick to characters used in modern written languages" to you?

Oh, wait, your example is going in the opposite direction. Never mind.

For stuff that might screw someone up even with no malicious actors, the most natural example that comes to mind for me is subscripts, like you might find in Julia-style variables.