They get frozen or deleted after some period of inactivity.
> Warning! All control consoles double as Firework Storage Lockers. On detonation of fireworks, please leap dramatically to the floor and feign unconsciousness. — Instruction Manuals for the USS Enterprise
@RMartinhoFernandes I prefer the one where the display next to the button says: "Press to test". Then when you press it, changes to "Test passed. Release to detonate."
@LucDanton Perfect. I just came home and read your comment about is_nothrow_move_constructible … and much to my surprise, this actually evaluates to false.
@KonradRudolph If you add an explicit specialization of std::is_nothrow_move_constructible for foo (which is a hack I think) that inherits from std::true_type you get the desired behaviour btw.
@KonradRudolph This particular trait is classified as 'missing' in the libstdc++ documentation. I don't know if that's up-to-date for 4.7 (given that the trait is in fact here). Or if there are open issues for it.
@RMartinhoFernandes I've never used Mercurial, was just trying to find out how to do it. Anyways, seems the clone only downloaded files full of garbage, so somethings wrong
You can't parse [X]HTML with regex. Because HTML can't be parsed by regex. Regex is not a tool that can be used to correctly parse HTML. As I have answered in HTML-and-regex questions here so many times before, the use of regex will not allow you to consume HTML. Regular expressions are a tool th...
@bamboon Oh! Well they're involved when e.g. you pass in a function to a Standard algorithm. Unlike object pointers they never had the problem of ownership. They're unlikely to blow up in your face, save for the pesky fact that they're nullable. I don't recommend using them as e.g. members or in data structures (whenever storing is involved) though; you either want a generalized functor or e.g. std::function for that.
@thecoshman "The right-shift operator causes the bit pattern in the first operand to be shifted to the right by the number of bits specified by the second operand. Bits vacated by the shift operation are zero-filled for unsigned quantities. For signed quantities, the sign bit is propagated into the vacated bit positions. The shift is a logical shift if the left operand is an unsigned quantity; otherwise, it is an arithmetic shift."
Lockless/lockfree programming vs. locks isn't about how long the lock is held. It's about determinism. Lockless algorithms can often be even slower that those using locking -- but (when correct) they guarantee forward progress, where locking algorithms generally don't.
it seems like with lock-free algorithms, even if someone super-smart implemented it, i would sitll have to expend considerable effort into figuring out how they work
Put the blocking code in a separate thread and wrap function objects in POST messages to communicate with the main thread. This way you can avoid data sharing.
@DeadMG The problem (and he does have a point) is that many (at least current) lock-free implements "leak" enough of the implementation into the interface that even using them isn't always easy. The same is true with some lock-based implementations, but they've been around long enough that most of the bad ones have simply disappeared (though ever year, a new crop of grad students creates more).
@DeadMG Yes, but at that level, you frequently don't need a parallel library at all. You can leave the code itself alone, and add #pragma omp parallel for, and get about the same effect (but much more portably).
I should also point out that TBB/PPL are far from the only libraries to provide things like parallel versions of standard algorithms. In fact, if memory serves the normal libg++ (one of the normal ones for gcc, anyway) has parallel versions of a fair number of standard algorithms, so you can use them without changing code at all -- just recompile with the right switches and you're there.
@DeadMG It's certainly cleaner and easier -- but you need a lot more than parallel algorithms to make anywhere close to optimal use of many cores for most tasks. From Boost, you're probably looking for something like futures, which are also cleaner and much closer (but definitely not identical) to task-based parallelism.
@DeadMG Parallel algorithms let you get a little bit of parallelism into basically serial code very easily. It's always a fork/work in parallel/join when that specified work is done, though. Threads let you run arbitrarily long in parallel, doing arbitrary "stuff", and only join when you have something like a data dependency that demands it. The exchange for that is that it's generally a lot harder to get it right.
the other thing is that you can fork into N threads, generally
a thread for each job is fixed in the number of jobs
if I parallel_for over an N sized range, then I can spawn as many threads as I like for a reasonable input size, whereas if I spawn one thread to render my game and another to simulate it, then I'm stuck at two cores.
@DeadMG You certainly have a point -- most threading code should decouple the task to be completed asynchronously from the thread that runs it. Thread pools are a good thing.
@DeadMG I would tend toward the opposite direction: it would be strongly preferable for the compiler to automatically figure out which for loops can happen in parallel, and do so without having to explicitly request it. There are definitely limits on it, but compilers that could do it to at least some degree have been around since the '70s. We should be moving a few steps beyond that by now.
@DeadMG Solving it in every case, is difficult, and as you say might be impossible. Solving it in a lot of cases isn't (as I said, Cray had compilers that did it reasonably well in the '70s, and they've improved since).
@DeadMG None of that has much effect on figuring out dependencies in a single loop. A larger system has more loops, but a single loop isn't necessarily a lot bigger or more complex. Oh, and Crays weren't used for trivial programs as a rule...
sure, but there's a big difference between "non-trivial programs in the 70s" and "programs whose instructions, let alone data, exist several orders of magnitude larger"
