Gödel's incompleteness theorems are two theorems of mathematical logic that establish inherent limitations of all but the most trivial axiomatic systems capable of doing arithmetic. The theorems, proven by Kurt Gödel in 1931, are important both in mathematical logic and in the philosophy of mathematics. The two results are widely, but not universally, interpreted as showing that Hilbert's program to find a complete and consistent set of axioms for all mathematics is impossible, giving a negative answer to Hilbert's second problem.
The first incompleteness theorem states that no consisten...

> @JakubM. @6502 just mentioned in chat, that with CUDA there is apattern (known as scan) that efficiently does an operation similar to yours. See developer.nvidia.com/cuda-cc-sdk-code-samples#scan - I think it might interest you if you still have the goal of optimizing this further – sehe 1 min ago

@FredOverflow Gives int for boost::optional<int&> and boost::optional<const int&>. Also for boost::optional<const int> but I don't know if that one is supposed to work.

I tend to not use decltype in generic code. value_type & friends are still the preferred options.

I suppose I could go WithQualificationsOf<Optional, ValueType<Optional>> yes. I'm still wary of those aliases that don't exactly do the same thing as the equivalent trait though (in this case, the Bare step is missing).

@RMartinhoFernandes Do you think a value_type trait that first searches for ::value_type and then ::element_type would be useful?

Hmm, I didn't consider element_type. So far I have ValueType simply as an alias for typename T::value_type (I really hate typing typename). But that would be better.

I took the idea from Bjarne's slides from GN, btw.

I wonder if a heart-without-a-pulse puts even less stress on the body

but maybe less stress could be a bad thing - one of the comments "If your arteries are accustomed to pulsatile, oscillating blood flow and it is suddenly switched to a steady, laminar flow, what effect does this have on the development of atherosclerosis, for example?"

@LucDanton Btw, I also have a ForwardedValueType alias for WithQualificationsOf<Optional, ValueType<Bare<Optional>>> (well, not quite, it's still buggy).

@ScottW well - sorry but someone else deemed the 'e.a.p.' flagworthy, and I wouldn't disagree. Not saying I'd flag something like that myself.

@CheersandhthAlf For once

@RMartinhoFernandes You see, that's where the entertainment value of the flags comes in. We wouldn't have that on the starboard, were it not for the flag broadcasts.

I mean, I'm not biding my time in the PHP room (or, god forbid the bin) just in case something particularly humerous comes along

@Xeo Why would you reckon there would still be a separate header? Oh well, it could have been. In general, like with tuple_io etc. none of the boost headers automatically include iostream stuff, mainly because, well it is a drag and drags in locales and chartraits and the whole shebang

@je4d It wasn't a fix, just a report with patch :) No one said it was applied

@LucDanton Your own statement (what counts as docs). You know, I do have a tendency to link to the messages I'm responding too. I find it makes conversation more tractable :)

@RMartinhoFernandes Is the template template parameter necessary? Would something of the style template<typename M, typename = EnableIf<is_monad_of<M, int>>> /* blah */ be too silly?

@sehe FTR I'm not a native speaker so that could be on my end.

In functional programming, a monad is a programming structure that represents computations. Monads are a kind of abstract data type constructor that encapsulate program logic instead of data in the domain model. A defined monad allows the programmer to chain actions together and build different pipelines that process data in various steps, in which each action is decorated with additional processing rules provided by the monad; for example a sequence of arithmetic operations can be controlled to avoid division by zero in intermediate results. Programs written in functional style can make us...

That particularly phrasing is by James Iry, from his highly entertaining Brief, Incomplete and Mostly Wrong History of Programming Languages, in which he fictionally attributes it to Philip Wadler.
The original quote is from Saunders Mac Lane in Categories for the Working Mathematician, one of ...

Come on, you love a simple question. Now, a fool can ask more questions in an hour than 10 wise men can answer in a lifetime (or somesuch, the Book Of Proverbs n:m)...

An endofunctor, T : X -> X A natural transformation, μ : T × T -> T, where × means functor composition A natural transformation, η : I -> T, where I is the identity endofunctor on X

Having briefly looked at Haskell recently I wondered whether anybody could give a brief, succinct, practical explanation as to what a monad essentially is? I have found most explanations I've come across to be fairly inaccessible and lacking in practical detail, so could somebody here help me?

I've always been dubious of the "it's a burrito" analogies etc. and IIRC the two things that helped me get monads were that C9 video that showed the maths and the 'You Could Have Invented Monads!' reading or something very similar to it.

Would writing (in C++) a utility that returns a boost::optional<U> given a boost::optional<T> and a (C++) functor and then read 'You Could Have Invented Monads' be a didactic experience I wonder.

@RMartinhoFernandes Mmm. Personally, reviewing and reiterating things I think I know inside out is sometimes didactic (in improving my conscious reasoning and the ability to explain to others. I'm thinking of other fields than programming too, now)

@MooingDuck The point is, you can write code that works for all monads. All the monad needs to provide is a bind operation like the one above, and a unit operation that constructs a monad from a value (basically, the boost::optional<T>(T) constructor here).

@LucDanton bind takes a function that takes a complex and returns a list of complex, and returns a function that takes a list of complex and returns a list of complex? // wild guessing. I guess currying is also involved somehow...

Yeah, I'm currently at it, but what's stopping me is all that . and *, and that Haskell allows ' in identifiers... any identifiers, not only function names. That threw me off a bit with the first bind

I get what they are now, thanks to "A monad is just a monoid in the category of endofunctors", but only in the abstract - it's still not clear to me how they're used in FP

@RMartinhoFernandes I know what function composition is, but a . b doesn't really lend itself to explaining how it works. :s I think I also had some problems with that chapter in Learn yourself a Haskell

@Pubby VS' "external tools" only lets me run one command. I might be able to fake it with a batchfile or cmd or something, but it's easier to simply whine.

// assume polymorphic lambdas
auto f = [](i){ return i + 5; };
auto g = [](i){ return i * 2; };
auto compose = [](a, b){ return [](x){ return a(b(x)); }; };
auto fog = compose(f, g); // f . g
fog(5); // 5 * 2 + 5

@RMartinhoFernandes hmm, when I view the history of that message, I get a banner saying "Welcome to SO chat, you need 20 rep to talk here". Nevermind, it only did it three times.

Validation of proof : First of all sorry, this has nothing to do with c++ but I didn't know where else to ask. Is there some kind of a community that reviews proofs? I want to publish an academic article, but I'm unsure whether a proof I wrote is correct.