Words Like Jared

@Alex That's really interesting. I wonder why that is.

@MartinJames "Their code is utter trash; being truthful would be mean." Calling someone's code "utter trash" is subjective. It's also probably doesn't help them and is arguably mean. While you're being truthful, you're only being truthful of your feelings, not of the facts. If you stuck to (so-called) objective, well-defined words in your feedback it would be easier to be nice. Everyone is a work in progress. Every expert started as a novice.

real-world-sized data sets instead of (falsely) assuming there's going to be more. There are 7-8 billion people alive today. If you had a record that corresponded to people it'd probably be silly to go much higher than a 64-bit integer to represent an unique idea because 2^64 gives you enough margin of how many humans there will be in the next decades/centuries. If you know your business problem well enough you should know what the real-world constraints are.

So I design my algorithm accordingly on the thing that processes the IEnumerable<PatientVisit>. Knowing the "real world" application of the thing that's being modeled can give you insight into making the algorithm not handle "infinity". Being able to handle arbitrarily large is when you write general purpose tools and frameworks, such as a database. When you consume the general purpose to create something specific it's cheaper to create a minimum viable product that is good enough for

Well if I was using an architecture where my domain model is at my center, then I may have a repository return part of my model (say an IEnumerable<PatientVisit>) for a specific PatientId. Then I have a method that takes in the IEnumerable<PatientVisit> (this is part of my domain - a third layer mediates the data and business here to decouple the two) and performs some calculation on an IEnumerable<PatientVisit> - implicitly I know there are only going to be roughly n PatientVisits

That being said the "most problems don't need proper treatment of infinity" is based on my experience, which may be totally different than yours - you could have a different view based on the problems you've had to solve - such as lots of academic or research problems or framework-level or language-level or something where it's more abstract and you can't make as many assumptions on how it will be used.

@NPSF3000 So if I'm dealing with a typed non generic IEnumerable - is it abosolute or relative? Suppose I have a concept of "patient" - I might want to view all "patients" which is absolute (and probably arbitrarily large - all people - billions potentially). However data limited to a particular patient, say their medical visits, then each person lives 100 years and has 365 days of data, then I have 36,500 records, roughly to consider. If you try to build computers to handle infinity you'll spend a lot of time. If you make more assumptions (and build a way to improve your software

when your assumptions are wrong or change you have a process to upgrade your software, including versioning and migrating. Sure you can write stuff to handle infinities, but most problems that need coding for don't need that (which is why languages don't usually have good processing on infinities, although if you needed that you'd pick a good DSL or cloud computing or AI, etc. to do the job).

What you're saying makes sense if you interpret me to mean "You can write code so that it's /always/ safe to call ToArray on an IEnumerable" is what you think I'm saying. I'm saying "You can write code so it's /sometimes/ safe/better to call ToArray on an IEnumerable." If the elements themselves are hard to compute (i.e. a database query with expensive aggregations) and they're small in total (small number of rows), it's fine. You should not write non-library level software unless you know roughly how big you're operating on. Universal quantifier vs. Existential quantifier.

@NPSF3000 Obviously if you're writing library level software (i.e. IEnumerable with a generic) you would not make such assumptions on the cardinality, although maybe you'd make one that it's computable by an integer (Say Count()). If I could make a suggestion it's better to try to figure out what the other person is meaning (like I did - I noticed your statements added up if I changed my quantifier from existential to universal). Most people are relatively intelligent when it comes to things they've thought through - they usually are just operating on a different experience set or vocabulary

There are not many things you run into that need software that exceed an integer by much. This is not because these things do not exist mathematically - it's because the people driving the need for software do not themselves comprehend such things. I love math and cardinalities of infinity - it's awesome - but those things do not generally have a place in enterprise software. You may live in a more research-oriented or academic environment (which is equally valid) but then are unable to understand the world does not operate using infinities because they get by with a finite approximation.

"should" != "you may be better off". Also you missed the context/presuppositions (i.e. you already have a method accepting an [] that does the same thing and you're planning on needing to expand the IEnumerable more than once...). .....

...I never said it did? IEnumerable.Count returns an int. Why don't you try putting putting something with more than 2,147,483,647 elements and see what happens. The API mentions an OverflowException which is what happens when the number of elements in source is larger than MaxValue. Like I said - good API == documented, tested, versioned, and lots of other things. good API != I didn't get a compiler error, so I shouldn't get a run-time error - if I did that means the API is bad. No it means you can't read and understand. (Judging from your responses, I think that's the case.)

Unless you have some constructive feedback for my answer to the question I think these comments are fruitless at this point because you're not addressing my points. Either I'm having a hard time explaining them, you're having a hard time understanding them or you're trolling (and I'm bad at discerning trolls).

Also the fact that IEnumerable<T>.Count() exists implies your B) case is the exception not the general rule. Methods don't need to handle all possible inputs that the compiler doesn't complain about - not even utility methods - that's silly - it's up to the method writer to implicitly or explicitly declare what inputs make sense - in this case why would you call Count on an infinite IEnumerable? Oh no Linq methods must be awful because they don't operate on infinite IEnumerable's....?

If you're writing something that doesn't specify the generic type argument, I see your point - that's a collections utility; it should work on any collection and not have to expand the IEnumerable, but I was assuming it was bound to a specific type like IEnumerable<Customer> - how many customer's will you have? There's only 7 billion or so people today, but you probably won't be that successful, so even if it was the entire dataset, it wouldn't be that much probably - why do you need to pull that in memory in the first place?

My assumption stated earlier was that you should have some idea what the IEnumerable you receive represents and code is not required to handle cases that don't make sense in "the real world" - it's a waste of your investor's money to design programs that handle huge data sets if they don't ever come up/it's not a requirement.

A) I wouldn't recommend RAM as the storage to do computations on a sufficiently large array... You probably don't need it in all RAM to begin with and if you did now your process has large minimum RAM requirements. B) I probably wouldn't have an infinite IEnumerable - I would maybe use a different API if I was streaming something and wanted it to run forever and do something on each frame.

@NPSF3000 Thanks! Well I said so that the IEnumerable isn't expanded multiple times; implicitly if the IEnumerable is expensive to compute (consider IQueryable<out T> : IEnumerable<T>) then you may want to make sure it's pulled into memory only once. Of course the disadvantage is you have the whole thing in memory, now, but you shouldn't be operating on an IEnumerable unless you have some idea how many elements could be in it or and whether or not it's pulling from the database, etc. I edited it to make that more clear - if you were confused, maybe I wasn't clear for others, either.

@NPSF3000 Knowing when to use it and when not to use is a big question, too big for this format on this site - I never said it was always misused. I gave OP a link to learn basic C# syntax and recommended OP to study C# considering the question that was being asked. Now you bring up a good point that I didn't give a concrete example of when to use it, even though I implied clearly such uses exist, so I could improve my answer and add that... thanks.

@NPSF3000 My intent was not to dissuade the use of method overloading - if it came across that way to many people then I did a poor job communicating my idea. I tried to give a more balanced answer with my edit this time. Let know if you can think of any further improvements.

@Joshua I guess I wonder why you couldn't just have funcname(IEnumerable<KeyValuePair<TKey, TValue>>, IEnumerable<KeyValuePair<TKey, TValue>>) and maybe call ToDictionary() on one if you need to for performance reasons so the IEnumerable isn't expanded each time...

@NPSF3000 I opened with an example of how method overloading can go wrong to confirm OP's suspicions of a language feature going awry. The thesis of my answer was that it is not in and of itself a bad idea (in C#) and that its usage is a tool that can be used properly or improperly. If you only understood the code example and not the explanation I provided around it I could see how you thought I didn't answer the questions of OP.

@Joshua It's not just limited to object - because Int32 can be promoted(?) to an object it works - if you had classes A and B such that A subclassed B you could make an analogous problem (I didn't demonstrate that because that was more complex). You can have ambiguity in default parameter values (which store the default value in the caller counter-intuitively) and variable length parameter lists as well to worry about.

@WDUK Having an object is not the problem, in and of itself. If you're used to languages like JavaScript you may be tempted to make types in C# object or dynamic - you should be explicit, generally speaking, when possible, in C# so you catch as much as possible at compile-time and not run-time. Sometimes you want to take in an object (i.e. serialization of a POCO to a string). I would recommend studying some C#. I used this site myself when I started ~5 years ago to learn most of the syntax, but I already knew Java: csharp-station.com/Tutorial/CSharp/Lesson01

@Joshua An IDictionary<TKey, TValue> is a IEnumerable<KeyValuePair<TKey, TValue>> so the compiler would have known what to do if you only had the IEnumerable<KeyValuePair<TKey, TValue>> overload...

@Joshua I misread you - my bad!