@Puppy the exception to that rule is cpu's. The modern ones are shaped to only fit in the socket one way, where the older one's pin configuration was shaped that way. Bent pins on a cpu can be repaired to a point if you happen to screw up an older one. Newer ones just make sure they plop into place evenly before you snap the retainer in place and apply power.
For a while now, I have been receiving inbox notifications for "proposed change", "topic request", etc. for topics on Documentation that I am not interested in.
When digging deep enough through the interface for those topics, can find where to disable the notifications as detailed in this answer...
An efficient implementation of IWPP on the Xeon Phi is a challenging problem because of IWPP’s irregularity and the use of atomic instructions in the original IWPP algorithm to resolve race conditions. On the Xeon Phi, the use of SIMD and vectorization instructions is critical to attain high performance. However, SIMD atomic instructions are not supported.
> Interestingly, to solve the problem the C++ refers to the C standard, claiming that C would drop all qualifiers for rvalue expressions that have scalar base type. It does this without refering to a particular text in the C standard, and in fact it can't since there doesn't seem to be such text.
is there a particular reason why would cmake segfault?
I feel I kind of broke my system... I can't update a few things because cmake segfault and I can't update because cmake segfault during the "configure" phase of cmake
@LoïcFaure-Lacroix To be honest, I like to pretend there's only Who Goes There? (the novella, which I assume is what you mean by "the book") and John Carpenter's The Thing.
@BartekBanachewicz I don't think so. You may need something to hold the camshaft ("camshaft holder tool" seems to give useful results), but that's easy to improvise (in fact, my dad's garage has only a homemade one)
@BartekBanachewicz Depending on its state and how much you value your time, that could or could not be an appropriate budget. Hard to tell without actually looking at it and knowing what problems you need to fix.
@Ven sure ... but only after you have start an online champion on how I am the elitest troll on the internet 2017 - the length of me not talking is negotiable, pending on my satisfaction of your champion
When everything starts crumbling down, people still have to live somewhere. Unless sovereignty starts shaking, then money would be not top concern anyways.
Wikipedia also says "Since the early 1990s, almost all gasoline passenger cars sold in first world markets are equipped with electronic fuel injection (EFI)." so not just in Europe it seems.
@Columbo in java true the primitive cannot be changed with reflection but the result of Boolean.valueOf(true).booleanValue() can change. But you never autobox Booleans anyway.
@ratchetfreak You know what's funnier? This ability to change private final fields is actually needed for some of the interfaces in the spec: docs.oracle.com/javase/specs/jls/se8/html/….
> Orthodox C++ (sometimes referred as C+) is minimal subset of C++ that improves C, but avoids all unnecessary things from so called Modern C++. It's exactly opposite of what Modern C++ suppose to be.
I currently hate Chrome. And Selenium. Chrome is simply not clicking through some links when I run my Selenium tests but it does when I do it manually. It is totally fucked up. And the same code works in Firefox.
And the corollary is that you cannot use RAII (at least not for memory), because you'll essentially be reinventing the parts of the stdlib that allocate memory.
@AldwinCheung If taken to its logical extreme that definition means that Orthodox C++ is simply C compiled with a C++ compiler, because the minimal subset of C++ that improves C is the one that makes int* x = malloc(n); not compile; you can't get rid of that feature, and you don't have to change anything to get it.
@R.MartinhoFernandes the irony of this is that glib and many other c library replacements treat things like memory allocation failures as a terminate() so this is really dumb
it's not even with classes (I'm pretty sure that inheritance would end up on the don'ts list), it's basically C with function overloading and pointer type safety
> General guideline is: if current year is C++year+5 then it's safe to start selectively using C++year's features. For example, if standard is C++11, and current year >= 2016 then it's probably safe. If standard required to compile your code is C++17 and year is 2016 then obviously you're practicing "Resume Driven Development" methodology.
This raises good objections, especially the first one gist.github.com/bkaradzic/…, but the only reply it got was "Exceptions are not some magic that you enable and your code is just exception safe. Style of code, support to be exception safe, and extra complexity is significant. And not worth for "rarely" used cases."
> No, I said if you don't care about precise memory management. Qt is usually used for utilities so memory requirements are a little bit relaxed there.
Let me translate: "I just make shit up as I go along. STL is bad, mkay?"
> From the other hand, primitive data structures, such as vector or list, give almost no profit, but are way harder to debug/maintain than hand-crafted linked lists and resizeable arrays.
> ISO with their policy of keeping standards secret and selling their texts for money, is the most dangerous terrorist organization in the world, way more dangerous that Al Qaeda. ALL they do is bad. So everything they do must be banned right off, without consideration.
> We have great news! Ghostery has been acquired by Cliqz, an awesome privacy-focused company. To reflect this change of ownership, our privacy policy has changed.
> The ubiquitous understanding that templates and variadic templates will produce much faster assembly because the C++ code will automagically vanish during compilation cannot be corroborated by my personal experience in decades of HFT and gaming, by no reputable peer-reviewed publications nor by anyone with some knowledge of compiler optimization. This is an ongoing fallacy.
@R.MartinhoFernandes Yes, they are. I have a new system. To avoid strings, every meaningful utterence in every human language is assigned an index number, and rather than the string itself, only its index needs to be transmitted. So far, we've gotten only to index 0: "This guy's dumber than a box of rocks."
@Mgetz That's not "homomorphic strings" (makes you sound like a gay basher), it's just an extreme form of arithmetic compression.
@R.MartinhoFernandes I call this all the time. Unfortunately, it never answers. :-( Must be blocking my calls. It's been pissed at me ever since I said it should really be a reference.
I'm redesigning ogonek's error handlers, and there's a special one that means "instead of using this handler to deal with errors, just don't do any error-checking at all".
@R.MartinhoFernandes At least offhand, it seems like it would be simpler to create an error handler that explicitly ignores any and all errors. Call it all you want--it just doesn't do anything about them.
@R.MartinhoFernandes Yeah, clearly it is slightly different--but if you already have it, there's obviously no point in just duplicating its (lack of) functionality.
Possibly missing context: this is for, say, decoding errors. If you just ignore them, you get an output that has less information that the input.
It does nothing with the errors, but it does provide functionality (I named it "discard" instead of "ignore" in an attempt to make that more explicit).
The special one is meant primarily to avoid redundant checks in places where I already have "no errors" as invariants.
@R.MartinhoFernandes Sure--it provides the rest of the system with functionality (otherwise it wouldn't be worth mentioning at all). It just doesn't embody much real functionality in itself.
There's two bits: checking for errors, which is encoding-specific, and dealing with them, which is not. The handlers do only the latter.
The "discard" strategy essentially skips bad input. Say, "A\x80" "C" would decode as ASCII into U"AC" because 0x80 is not valid ASCII (because > 0x7F) and gets discarded. This special one I'm dealing with would instead mean that the code never actually checks > 0x7F.
I guess it's just a dispatching tag to a more efficient algorithm and not really a error handler.
@R.MartinhoFernandes So you want to assert that since the error wasn't supposed to be checked for in the first place, that it's really not acceptable if the error handler was called.
Right, that was my original intention. But I think I'll just make it not meet the concept requirements in the first place, since it needs to be dealt with a separate overload anyway.
@R.MartinhoFernandes Yeah--you can basically go the "implicit" route, with a do-nothing error checker, and a do-nothing error handler, and leave it to the compiler to figure out that in this instantiation, those paths can be optimized out. Otherwise, you do it explicitly, in which case conformance to a common interface/concept will probably be irrelevant.
Also, I wrote a script that parses the mappings from here unicode.org/Public/MAPPINGS, and that's already some hundred encodings no one ever uses, for free. Even less likely you'll be writing your own unless it's really some custom bullshit.
Though I plan to include UTF-9 and UTF-18, just for kicks.
This discussion today on the Core Guidelines repo issues is probably of broad interest. It’s regarding why we chose to annotate not_null<T*> rather than the reverse in the Guidelines and the Guideline Support Library (GSL). Pasting here: I would take this interface reduction one step further and make an un-annotated T* implicitly “not null”. I […]
@Ell re type discrimination: no, you have to pass a discriminator in as a value. This can be done implicitly with type classes (see also Typeable class in Haskell).
user1804599
The point of parametricity is that the behavior of a function is solely derived from its value arguments (this includes type class dictionaries).