@JerryCoffin Thing is, software design is such an abstract art. There's no definitive recipe for success. I keep reading things on design where it's like "Design to allow change" well gee thanks that reall points me in the right direction. Or even "design so it's easy to test because usually classes that are easy to test are more robust to changes" yet another vague answer. I wish there was a repository of "great software designs" with an explanation as to why they're good.
(I had to stop apparently there is such a thing as a message that's too long)
That reminds me of something I was thinking about a while back: is there enough redundancy in the data you're writing to disk that it would be worthwhile to consider trying to use one of the standard lossless compression methods on it?
@Borgleader I'm long-winded enough, I run into that all the time.
@Borgleader Yeah -- that's where experience comes into it. To be honest, a fair amount often comes down to simple luck, at least in my experience. Quite a few changes I've had to do weren't things I planned for at all. Some ended up easy quite by accident. In other cases, things I thought I'd planned for ended up enough different my plans accomplished nothing. Anymore, I try to avoid obvious traps, but otherwise tend toward the YAGNI viewpoint.
@Mysticial More a case of OOA fail -- they tell you to think of the "nouns" in your description of a problem, and build classes to correspond to them. The problem is that most of those are so high-level that if you do that, you end up with a few classes so huge you've accomplished nearly nothing.
@Borgleader Nearly always a mistake, IMO. Accessors usually mean you've defined a member as one type -- but assuming your accessors do something meaningful, you're using them to imitate some other type. If so, you should usually factor that out to become a real type of its own.
@Mysticial That's usually the goal -- access the underlying representation via an abstract enough interface that you can change the representation without affecting the code that uses it. Hard to do that while maintaining maximum performance though.
@JerryCoffin That was the original goal. I had a variable that was the word-size. And it was supposed to be able to switch back and forth between 32-bit and 64-bit.
However, I was never able to do 64-bit due the lack of a 128-bit integer type. So as new code came piling on it would work on the 32-bit word. But never tested on the 64-bit word.
And after a while - due to timing pressures of the the world-record runs, I just started to hard-code 32-bit values.
So it made impossible to ever switch it to 64-bit. Even if compilers did support 128-bit integers.
All the code was written and tested for the 32-bit word. But never on the 64-bit word. And it was almost certain that everything would break if the switch were ever to be done.
Because of the need to have everything work on two different representations, it inherently blocks me from making stupid mistakes like doing word-size dependent code.
@Mysticial Yup -- for vaguely similar reasons, I don't consider a computer set up for development until I have at least two compilers installed and ready to use (but things have gotten better -- at one time I routinely tested with 4).
I think I might have overdesigned it a bit too. Currently, the program can use the 32-bit path on 64-bit and vice-versa. In fact, both 32-bit and 64-bit paths are compiled together at the back-end. So the user can pick whichever to use at run-time.
@Mysticial That does seem a bit excessive -- I find it hard to imagine a benefit from running the 32-bit path on 64-bit hardware.
@Borgleader You're not the first to say that. Then again, at the time I pretty routinely found new portability problems with every one of the 4 compilers I kept installed...
@JerryCoffin Yeah. I basically moved the word-size selection to the middle-end of the program instead of the back-end.
The back-end provides both 32-bit and 64-bit implementations of everything. The middle-end selects one. And the front-end uses that chosen word-size.
But yeah... that's my experience in software design. Never had a precedence. Never learned from anybody else. Done all by myself with my own guns at my own feet.
@Mysticial Question is whether there's any real reason for run-time selection at all, or whether it can be selected automatically at compile time and be done with it. For that matter, is there any longer a real reason to support 32-bit at all? Is somebody going to set a new record for number of digits computed on a cell phone?
@Mysticial Ultimately, I'm not sure how much anybody learns from anybody else. I've read more books than I could carry, and did darned little to help me avoid the same mistakes -- at best, I recognized them as mistakes a little quicker.
@Borgleader To the console? Do you mean on Windows? If so, it's trivial with printf, next to impossible with iostreams. In theory, wcout is what you want. In reality, it just won't work (at least in all the testing I've done, though I'll admit that isn't with the latest compilers).
The basic idea that should work is to set up the console to use UTF-8, and set up a codecvt facet that produces UTF-8. On Windows, however, the UTF-8 codepage is completely broken, and the compiler doesn't (or didn't used to) include a UTF-8 codecvt facet.
@Borgleader One thing to add though: hidden in the bowels of Boost, there is a (working, portable) UTF-8 codecvt facet. I still haven't gotten console display to work right, but it's at least useful for producing UTF-8 files and such.
FWIW, some test code I wrote some time ago: ideone.com/wOBvd6. If memory serves, the commented-out section produces correct output -- but using wcout fails utterly.
I am curious why is it that std::vector is so much more popular than std::deque. Deque is almost as efficient in lookup, more efficient in insert (without vector::reserve)and allows for inserting/deleting in the front.
Herb Sutter once recommended that if you want to use vector, just prefer deq...
@ThePhD Because it comes first. If you swap them then deque will need more warmup. However, it will still be faster because of less copying when reallocating.
I had a program where I generate a list of QImage objects from a directory recursively. Switching from vector to deque greatly improved speed. It's not very friendly to reserve many megabytes up front if you don't know you're gonna need that much.
C++ only has what it explicitly adds from C (and that is pretty much limited to the standard library; all the rest is redefined, often in a compatible way, but not always)
@ThePhD Iterators only. Ranges have been discussed, but I don't recall having seen a proposal they could accept into the working paper for the next standard (i.e., something that actually proposed wording and such).
@ThePhD I'd also note that Stepanov is a lot less excited -- he commented that ranges really only work for a limited subset of algorithms (and noted that Andrei had really only implemented something like 10 algorithms).
@R.MartinhoFernandes It might not be -- he may have characterized it unfairly, or my memory of what he said may be wrong. Or maybe he's thinking at a higher level of abstraction where (for example) all versions of "search a collection" are treated as a single algorithm.
@Pubby IMO, it has some good points, but not enough points that are enough better to justify switching. If it had come along before C++, I doubt C++ would ever have happened. Coming after, it just isn't enough of an improvement to justify the trouble.
@Pubby I put a function in a header, I'll get redefinition errors if the header is including into more than one compilation unit. So I'm asking if inline will prevent it, or do I also need static.
@Mysticial I don't think so, except on old enough C compilers that they simply don't support inline (but I'm uncertain -- I've never used a C compiler that supported inline).
@Pubby There is some metaprogramming stuff that in C++ has to be done with tricks and hacks: static if, an operator that tells you if something is a valid expression (no need to write those SFINAE-based traits all over), other minor stuff.
@Pubby See my earlier comments. It's nice, but not enough nicer to justify a switch for most people. In particular, I think it's at least generally perceived as really only competing directly with C++, not for projects where you'd more often use, say, Java, Python, Ruby, etc.
Oh, just to clarify: I have installed it and tried it, but never put it to any serious use (and no longer have it installed). My timing was probably somewhat unfortunate: I first got it just before D2 came on the scene, so I tried it a little bit, then everything I'd done broke completely. Then D2 was new and being changed pretty quickly, so literally every time I updated to fix some bug, nearly everything I'd written broke completely. That got discouraging very quickly.
They will tell you that the GC is not forced and you can disable and blah blah it is awesome. But then you use, say, string literals or array literals, and you are immediately leaking because those are GCed.
Not to mention that the standard library probably does not have a single instruction to clean up memory.
Most of those are faults of the implementation, not the design, but there aren't many alternatives around...
The current GC is also pretty primitive (basic mark/sweep) and completely broken for some kinds of situations. For example: d.puremagic.com/issues/show_bug.cgi?id=7251#c0. Also note this issue marked as "resolved", but nothing was actually done to resolve it. Doesn't exactly inspire tremendous confidence in the development team.
@JerryCoffin I read a study somewhere that essentially said that in order for GC to perform as fast as explicit memory management you need like 3 or 5 times as much memory used by the explicitly managed program
I'm thinking that template <...> could be interpreted as a fact in prolog engine, and then you could do predicates which would essentially be a concept check
@Insilico The study I saw showed closer to 7 times as much to be at all sure, but yes. Make no mistake: especially when it comes to multithreading, GC has some real advantages.
@JerryCoffin LOL. And they're arguing that it's not a bug, but if it is, it's inevitable. :))
> The static data segment and the stack generate _always_ contain false pointers. So even if you're not generating them yourself much, they do exist and things will get stuck.
@Pubby GC can be made to work well. The problem is that most implementations haven't caught up to what Self (for one example) was using ~30 years ago. OTOH, good Lisp implementations (for one example) really do work quite nicely.
@Insilico Self used Generational Scavenging. About the only currently popular system that uses the same is .NET. It's a copying collector, so you only pay to keep objects alive, not to get rid of garbage. It also notes that if objects have lived a long time, they're likely to survive longer, so it doesn't try to collect them as often.
A lot of it depends on good support from the rest of the system though. For example, the problem above in D's collector seems to indicate that they're using a conservative collector, which means it can't compact the heap (prevent fragmentation) and doesn't know for sure whether a memory region is reachable or not (assuming anything that could be a pointer really is).
That's sort of all right if you're tacking a GC onto a language that doesn't support/depend on it (e.g., the Boehm/Demers/Weiser collector for C and C++), but unacceptable if you truly depend on it.
@Insilico It helps out a number of things. First, if you share objects between threads, reference counting can be really slow (reference counts need to be synchronized). If you do manual management, you end up with either locks in the heap manager, or a number of separate heaps (e.g., one per thread). Then freeing memory gets ugly, because you have to release a block back to the heap it came from.
You end up with a fully connected graph from threads to heap managers. Works, but definitely non-trivial.
There are several problems that become trivial if you are allowed to simply leak the memory (in a way; obviously, the GC will pick that up, but you are essentially letting it leak).
@Insilico I can believe that: almost every object in C# has (I believe) 4 bytes of overhead attached to it, irregardless of what its for. Then there's other things that can be attached to it, which continues to stack on the overhead.
@R.MartinhoFernandes You do realize, of course, that this is a nonsense word, don't you? Nobody here says "egg shell predetermined breaking point causer".
http://ideone.com/a3qEGa Here is the link to my code. It is a naive but correct implementation of Dijkstra's algorithm for shortest path. I have tried to explain my doubt through the comments.
Question: if you have a std::vector with an excessively small bytesize for its elements (say, 4), do any compilers avoid heap-allocation and just allocate the memory on the stack?
@TonyTheLion Yes, but I even find out about you what you didn't want me to know. Like that you spend your evenings with coworkers now. That's good, I guess. Better than being home alone and depressed.