I did, but that's not helping much. My dad was trying to explain it to me and says that first they all execute and output AAA and then the for loop lowest will execute 26 times and say AAB AAC AAD AAE etc
> A monkey is a primate of the Haplorrhini suborder and simian infraorder, either an Old World monkey or a New World monkey, but excluding apes. — Wikipedia
@thecoshman They are primates, too, but not monkeys.
> Being an ape, he is known for his violent reaction to most people calling him a "monkey." — The Librarian
@sbi so there was a common ancestor to lemurs and monkeys, lets call it lemkeys; and then lemkeys and apes share a common ancestor. Also IIRC lemurs evolved on Madagascar, rather then simple finding there way their
@thecoshman There's a family tree of the primates at Wikipedia. (You might need to scroll down a few lines if you have a low resolution.) That should enlighten you.
Well, I assume. I haven't checked their implementations.
The gist of it is that you can't use placement new to construct over a dead reference or const object, and that extends recursively to types that hold a const member of reference member.
So actually no UB until e.g. operator= destroys and reconstructs such a type.
And in fact such a type will have deleted assignment operators by default (which Boost.Variant will catch). But it is possible to write struct evil { int& ref; evil& operator=(evil const&) {} };.
So for such a type evil e = { i }; e.~evil(); new (&e) evil { j }; is UB (or maybe it's UB if e is used). And I expect the operator= of Boost.Variant to do that.
@RMartinhoFernandes What if it's boost::variant<evil, int> and the RHS has its int member active?
@RMartinhoFernandes I presume that the restriction is here to allow an implementation to treat const objects as really, really const, no loopholes allowed. I.e. in const T t = {}; rest_of_the_program(t); std::cout << t;the last statement can't be affected by the rest of the program.
And by that same token, references.
@RMartinhoFernandes Oh wait, is that paragraph 9?
Doesn't mention references though, and no recursive rule.
I like what I've done with it recently, although I'm a bit disappointed that GCC won't let me do make_overload(f, g, fallback(h)); have to make-do with putting the fallback(h) in first position for the time being.
@RMartinhoFernandes It can hold any error (i.e. it holds an std::exception_ptr behind the cover).
If you want conceptually speaking an std::future holds such a type. Either a value of a given type, or an exception of any type.
I struggled for a while to understand why you usede make_overload_over<...>::make instead of just a free function, until I tried to unpack the types on a tuple onto a variadic function template.
Lets say I have a class Handler with some subclasses like stringhandler, SomeTypeHandler, AnotherTypeHandler. The class Handler defines a method "handle" as a common interface for all the subclasses. The logic to "handle" is ofcourse completely different for the different handlers.
So what I nee...
@RMartinhoFernandes I haven't even tried. I still think it's not doable (for having attempted long ago right before I settled on make_overload_over as a compromise). A bit of a shame, as it's usually nicer to pack the signatures into a tuple.
I.e. the conflict is that you need the elements of the sequence right away (can't use deduction since the argument is overloaded), but can't partially specialise function templates to match those elements.
just checked my junk mail. apparently I have won a free Samsung Galaxy Nexus and all I have to do to claim my prize is to give my address, email account password and my dad's ATM PIN. Seems honest and authentic enough...
@RMartinhoFernandes Well if it come to that I'd rather have overload(overloaded_name) be something first-class in the language; I think overloaded sets make for worse second-class citizens than variadic packs are in C++.
seriously though, reading junk mail is fun. I often do it when bored, it makes me feel so lucky. I won a Toyota Prado only 2 days ago in an anonymous imaginary lottery too. :D
@JohnSmith depending on what you function is doing, you might be able to look into making it (more) parallel-ised and/or making use of pre computed data values
If the recursion is recalculating values for the same inputs more than once (like the dumb Fibonacci things you see around), memoizing would indeed help.
And it's not exponential... it's logarithmic. But it's just large and with lots of repetition
Right, because it currently uses four input variables that don't have a lot of repetition
but the outputs do
and since I have %M operations I am wondering if this can be wrapped up somehow
simplifying the inputs in turn, or figuring out when I can bail out even earlier in the loop given that I've already encountered some particular position earlier
I'm adding support for volatile for no other reason other than being generic. And that it comes for free of course; it's not like I want to actually put the effort to have it.
@JohnSmith Yes, because you can speculatively evaluate iterations for k in range(0,y+1, 2). count is the output but it's not an input to the recursive part.
CPU threads will soon run out and got give you that much benefit. you need to be able to throw a lot of threads at this, such that the for k in range(0,y+1, 2) can be done for all values of K at once
Q: When a cart flys off an edge and hits another set of tracks, can it keep going? A: As it stands, launching from one track to another is 100% effective, if you have it lined up.
if you have 1000 values of K and work on them all at once, you have more or less reduced execution time to a 100th (a fair few things assumed admittedly)
@RMartinhoFernandes Jython doesn't either. (Jython is actually kind of cool the way you can load in arbitrary Java classes and interact with them in python)
@sehe Not really, the number of instantiation can get quite high. E.g. three-way visitation means there are instantiations on the order of a*b*c where a, b, c are the 'size' (number of possible active members) of the arguments.
@RMartinhoFernandes Although, it looks like jython only implements python 2.5. . IronPython's docs says it supports 2.6.. but it's numbered 2.7 now? Maybe they forgot to update the documents?
Making gratuitous use of my expression template instead of hand-writing the polymorphic functor makes the compile time balloon up to 12.6s. Oh dear. Let's time Boost.Phoenix instead.
C++ allows a compiler to precompile all the standard headers and then pull them all in when you include a single one. With a mmap'able precompiled header format, that would be pretty practical… when it catches on, they can introduce #include <std> and we never worry about individual ones again.
Given that Boost.Phoenix makes the preprocessed source have 134k lines while my C++11 emulation (which takes longer to compile) 'only' nets 36k lines I'm not entirely sold on the 'headers are evil' problem.