Okay, I have a weird need. I need a way to tell the compiler that I want a particular virtual function to be overriden in all derived classes, but at the same time it can't be a pure virtual function, because I need the top level type to not be abstract :|
@ChemiCalChems in a function returning X* i have a switch case statement wherein i return various X* depening upon function's parameter but i gurantee that the paramter is only specific values so i don't have any default case or other case so it is natural by the compiler to warn me that function returnin X* not returning anything, so what should I do?
@ChemiCalChems Unless the data cannot be retrieved, but the lack of data is data (web services for example), there should never be a point that the data becomes null; throw an exception when it cannot be made...
@ChemiCalChems It's about being strict about what's permitted. std::find always returns a value- the iterator. Furthermore, std::find has explicitly as part of its contract that it may return the end iterator. If you have a function where it is not part of the contract that it can return nothing, you should never return nothing.
@puppy oh. @Chem when it is on line `return *r` the value of r is 0x62f3c0 and then it goes to line `vector<X*> vec =...` then r changes to 0x7ffff7839b78
I have a suggestion for his list: Beginners often define operator overloads in the global namespace because they think that's needed to make them visible to other namespaces.
I think learning the basics of name-lookup and ADL is useful even for beginners.
It's not useful to experts, because they already know
This was, obviously, only to be expected https://www.youtube.com/watch?v=Y4Zdx97A63s - I personally worry about the hormones of male presidential candidates
@StackedCrooked My suggestion: "writing a specialized operator< for a custom type in order to make it usable as keys in std::map instead of making a custom binary predicate comparator for the map"
Sure, but I mean the cases where it either a.) it isn't quite clear what operator< should do b.) it does a weird thing, like comparing a person by how many items he has
Otherwise when it's quite obvious what does a comparison mean, then sure, go ahead
@milleniumbug Hehe. That's evil. I'd like to think it's UB
Because, as I see it, it would forward value_type const& into the copy constructor for value_type, but it will do the reallocation first. Making it a dangling ref
@StackedCrooked He makes a "correct" point (if you pass 1 argument and don't want to get conversions, use push_back).
But it's very very meh and moot as there literally never was any reason to call a constructor besides copy/move in that case, making emplace_back clearly irrelevant.
Emplace back is expressly for constructing, i.e. it is explicitly calling constructors. Don't be surprised if it... you know, call constructors.
My current approach is to choose push_back by default unless there's benefit in using emplace_back. If both are equally fine, then I use push_back.
I've noticed a colleague starting to use emplace_back everywhere.
There's the belief that emplace is magically faster than push_back.
And I hate this code where stuff is sprinkled with magic dust to make it go faster. Like he used to put throw() on all his functions.
And now he discovered constexpr. Everything is constexpr.
I recently optimized a very important bottleneck in our codebase by replacing his low-level sem_post trickery with a simple mutex and condition variable. That felt pretty good :)
I did really fine tune it though. Only calling notify if the container was empty before. And not notify under the lock. And use batching. All the stuff I toyed with on coliru last two years :)
@StackedCrooked It can be :) It's not always applicable. It's just more of "say what you mean" and in [l|x|r|pr|...]value land you'll always have options
That's ... only a smart choice if you don't ever expect to starve threads.
@StackedCrooked Indeed. I think people who over-use emplace try to cut down on the "thinking" part. Which is nearly always a bad choice, unless (a) you don't need c++ anyways (b) you have the proper abstraction hiding the performance sensitive things anyways
The problem is that if you notify under the lock then the thread that wakes up will need to lock the mutex. And it will fail, and go to sleep again. Perhaps the kernel is smart enough today to avoid that. But I heard it can be a problem.
@StackedCrooked I love emplace_back. You should too. I don't like mono-thematic thinking coworkers.
@StackedCrooked It can't. Of course the woken thread automatically gets the lock, as guaranteed by the kernel. Anyhoops, that's assuming std::condition_variable::wait_until(lk, lambda) interface
@sehe Very often he does things that makes code slower. Like adding an empty destructor with throw() to pod-like types. (He once heard that throw() can sometimes make the compiler optimize better.)
He likes to see his magical speed sprinkled everywhere. He'd be better of by measuring stuff and learning proper C++.
@StackedCrooked I fully admit that sometimes I cop out because my mind doesn't have the capacity to remember the 12x12 matrix of autogeneration scenarios :)
But at least I know what I know and when to look it up.
I think it's in the >>1 vs. /2 realm there; the compiler will optimize both equally well. Of course bitfields have less features - but that makes it the stricter contract, which has some merit
what is "clean" about locking? And if it turned out to be unneeded, then why didn't you just delete the code?
Fix the code and clean it up.
explicit VlanHeader(VlanId myVlanId) noexcept {
this->vlanHeader[0] = 0x81;
this->vlanHeader[1] = 0x00;
// --- OK to reinterpret_cast + write the value (no compiler optimization issues):
// Since this->vlanHeader will not be returned or used in further code in this method
*reinterpret_cast< std::uint16_t * >(this->vlanHeader + 2) = htons(myVlanId);
}
^ Compiler warns about strict-aliasing.
If the compiler warns about strict-aliasing then you don't counter-argue. You fix the code!
So stupid.
Like the compiler is gonna back down and say Oh hey I guess you're right.
that'd be an infinite loop. Can the compiler detect that the decltype throws it in an infinite loop and instead evaluate the 2nd part (which is gonna be false, and thus stop recursion)?
I am trying to understand why a piece of template metaprogramming is not generating an infinite recursion. I tried to reduce the test case as much as possible, but there's still a bit of setup involved, so bear with me :)
The setup is the following. I have a generic function foo(T) which delegat...
@Ven I thought you meant as a boolean shortcut in costant context. That can't work, because it already is an instantiation error. (Would be nice to have decltype_or<void>(expression) that returns void if expression is an instantiation failure)
To keep things easy for my self I always make every instantiation condition explicit and tend to group overloads into classes. Overloads of member functions do not exhibit partial ordering semantics found elsewhere, and it gives me peace of mind that I can forget about it then.
Disclaimer: I'm not a big fan of meta-programming. I find C++ treacherous enough as it is.
