High-altitude nuclear explosions (HANE) have historically been nuclear explosions which take place above altitudes of 30 km, still inside the Earth's atmosphere. Such explosions have been tests of nuclear weapons, used to determine the effects of the blast and radiation in the exoatmospheric environment. The highest was at an altitude of 540 km (335.5 mi).
The only nations to detonate nuclear weapons in outer space are the United States and the Soviet Union. The U.S. program began in 1958 with the Hardtack Teak and Hardtack Orange shots, both 3.8 megatons. These warheads were initially carried...
meanwhile, I feel like starting a petition to get the BBC to apologise for its part in the Western propaganda campaign last year, whereby all the Syrian rebels were deemed freedom fighters and Assad's nomenclature "they are 'terrorists'" was always accompanied by incredulous quotation marks (notice how it turned out to be completely true and we are now paying the price for every State institution who made this arrogant, knee-jerk misinterpretation)... but I don't know how to phrase it.
Does anyone recognize this problem statement? "Task: Copy the contents of boolean variables h1, h2, h3, h4, h5, h6 to l1, l2, l3, l4, l5, l6, respectively."
@LightnessRacesinOrbit Well, there are poor areas. In those areas there are automatic guns. The automatic guns creates the hierarchy. Now Obama decided with a few $millions to export a few more automatics into the region.
Here's my code:
int f(double x)
{
return isnan(x);
}
If I #include <cmath> I get this assembly:
xorl %eax, %eax
ucomisd %xmm0, %xmm0
setp %al
This is reasonably clever: ucomisd sets the parity flag if the comparison of x with itself is unordered, meaning x is NAN. Then setp copies ...
I have a quick question (I hope!). In JS, why does isNaN(" ") evaluate to false, but isNaN(" x") evaluate to true?
I'm performing numerical operations on a text input field, and am checking if the field is null, "", or NaN. When someone types a handful of spaces into the field, my validatio...
Soooooo isNaN is apparently broken in JavaScript, with things like:
isNaN('')
isNaN(' ')
isNaN(true)
isNaN(false)
isNaN([0])
Returning false, when they appear to all be... Not a Number...
In ECMAScript 6, the draft includes a new Number.isNaN but it looks like (imo) that this is also broken...
I'm actually having a surprisingly hard time with this
this is where niebler introduced his hack-ish placeholders
thinking about refining made me wonder why I bothered with struct Concept { template<typename T> auto require(T&&) -> ...; }; instead of moving the template to the class itself, i.e. template<typename T> struct Concept;
thinking about refining made me wonder why I bothered with struct Concept { template<typename T> auto require(T&&) -> ...; }; instead of moving the template to the class itself, i.e. template<typename T> struct Concept;
Stupid idea: template<typename T> struct Numeric { template<typename X> auto requires(X x) -> … };, then Constraints<Numeric<T>> ‘finds’ T and does the right thing.
… struct constraints_impl<Concept<Ts...>>: concept_to_trait<Concept, Ts...> {}; if you will.
Here's my code:
int f(double x, double y)
{
return std::isnan(x) || std::isnan(y);
}
If you're using C instead of C++, just replace std:: with __builtin_ (don't simply remove std::, for reasons shown here: Why does GCC implement isnan() more efficiently for C++ <cmath> than C <math.h>?).
He...
I’m wondering if you can improve diagnostics by going template<typename checking, …> bool check() { static_assert( checking(), "Check failed" ); return true; }, so that you get checking = Concept<T, A, B, C> in the instantiation stack.
Now I’m wondering if I can trigger a diagnostic by injecting dummy values. I.e. constrained_function(diagnose(x)) performs the constraint check as if constrained_function(x) was done, but hard error instead of SFINAE.
@Rapptz I’ll think about it. Sounds promising though.
Although you’d want auto refines(T&& t) -> parents<Foo<T>, Bar<T>>; no? :)
So someone posted a piece of our internal library on Roflcopter. Nice. (I am half sure this piece of the library was updated to actually use atomic builtins some time ago.)
Honestly I think it’s fine if we talk between us using a ‘concept assembly’ of sorts, while still being free to use as many clever helpers as we care to. E.g. the whole { expr } vs { expr } -> T (and even { expr } = T) stuff, having one overloaded expr<decltype( foo )> vs expr<decltype( foo ), T> (and then how do you go about exact matches?) is too clever again. So I would like to discuss using valid_expr and convertible_expr, even though I understand that practically speaking a
clever expr to handle both makes sense.
@Rapptz Pinpoint the first broken requirement, although that’s begging to define ‘first’. And that’s an interesting question ;) Pinpoint meaning it’s obvious which concept was broken for which arguments (e.g. foo being not movable).
When I do stuff like for_each(some_tuple, [](auto a) { some_constrained_function(a); }) it’s expected there is a stack btw. I want a good diagnostic to help me figure out whether it is an instantiation of the constrained function, or of for_each that led to an error.
@Rapptz Let’s call that one the clever clauses or expr or whichever. I.e. a clauses<decltype( foo ), Foo<T>> that’s equivalent to a not-so-clever clauses<valid_expr<decltype(…)>, refines<Foo<T>>>.
I care about discipline in that kind of metaprogramming because when clever things go wrong, debugging is nightmarish. Putting everything inside refines<>, valid_expr<> and so on is slapping a type-system on top of what is essentially dynamic typing with duck typing.
user1804599
clang highlights differences between template parameters in type mismatch errors but that's not enough. :v
ok, does anyone know what the second part of the following paragraph is talking about:
The excavation is usually done larger than the proposed house to allow for landscaping, paths, driveways and to allow the external finish around the slab to fall not less than 50mm away from the building for the first 1.0m
Bikeshed time: InvokeOrElse<Foo, void volatile*> results in typename Foo::type unless it SFINAEs out, resorting to void volatile*. Better names (e.g. not as threatening)?
U J::Method<int> J::Ref::m<int>(std::string, std::string)
0000000000001220 T J::Ref::Ref(JNIEnv_*, _jobject*)
00000000000012c0 T J::Ref::~Ref()
0000000000001770 W J::detail::MethodCall<int>::call(JNIEnv_*, _jmethodID*, J::Ref)
0000000000001730 W J::Method<int>::~Method()