@WGhost I've never been able to find any study that confirmed it--but your taste buds get replaced every ~2 weeks, and after ~40, there's a slow loss of regeneration (and although less seems to be known about it, you seem to slowly lose your sense of small too). At the same time, at least some studies seem to indicate that your brain continues to develop, so even though the sensing part isn't as sensitive, the processing afterward probably becomes more developed.
Neurons in the cerebral cortex are never replaced. There are no neurons added to your cerebral cortex after birth. Any cerebral cortex neurons that die are not replaced
@Telkitty Didn't the amazon bloatware phone cost $1?
`In a notice to customers, the company said it was receiving 600,000 hits a second on its website, although it did not say how many of those hits converted to real orders. By comparison, Google processes about 40,000 search requests a second.` WAT.
how do I import stuff from a python package that installs itself in a weird nested folder? e.g. SCons sits in Python27/Lib/site-packages/scons-2.4.1/SCons/__init__.py :/
@LucDanton site-packages is not the problem, I can import other packages from there just fine - just not SCons because there is no SCons (only scons-2.4.1) ._.
@Borgleader Part of the basic idea is that the file system can expand onto more disks whenever needed, so when you start to run out of space, you don't (for example) have to explicitly copy data to a new disk--instead, you plug in the new disk, run a utility to tell the file system about its existence, and the file system starts to use the extra space.
@Borgleader Pretty much, yeah. You can do that with RAID (for example) without ZFS though. What ZFS allows is doing it semi-dynamically, so you can add new disks to a file system without tearing it down and building a new one.
@Borgleader On reasonably current hardware, yeah, mostly. It is a bit more dependent on caching than (most) older file systems, but it includes a couple levels of caching.
@Ell COW? as in its a diff of the previous one or something? like you have a base backups and the following ones are only changes compared to the base?
@Borgleader COW does't imply base+diffs, but does make the latter fairly easy to implement. ZFS also includes de-duplication, so (for example) if you're storing a bunch of VM images, most of the base parts of the image (the kernel, drivers, etc.) will end up a little like a shared_ptr to a single block of data.
It's great on Windows. But disappointing on Linux. It still beats everything else on Linux, but it seems that Linux condition variables aren't as efficient as the Windows ones. Though I'm 70% sure it's something more fundamental such as how the Linux scheduler works.
@Xeo apparently this may or may not be hijack-resistant, although as you can tell it’s fairly annoying to write. it gets better for operations that aren’t const-overloaded though (then you just have the as_const(arg) attempt).
So the pool, while originally done to narrow the performance gap between Windows and Linux has actually made it wider - while speeding things up on both platforms.
Pool size is unlimited. The # of threads it will spawn is equal to the largest # of overlapping tasks. Task duration can range anywhere from microseconds to minutes.
@HubertApplebaum I can't say whether a queue would've been a point of contention since I designed it without a queue in the first place in the expectation that it would be a point of contention.
@Mikhail Back in the Nehalem days, memory speed was partially limited by the number of DIMMS per channel. More sticks, lower speed. I'm unsure of the situation now with the LRDIMMs and stuff.
@HubertApplebaum Basically, the process of finding an idle thread (when one exists) is completely lockless. It doesn't even use any expensive instructions like atomic increment.
Once it finds (what it thinks is) an idle thread, it does compare-swap on the "busy" flag. That will officially "capture" the thread. At that point, there's a condition variable/lock/signal to wake up the thread. But we're now isolated on a single thread. So it won't clash with the gazillion other threads trying to put stuff in the pool.
@HubertApplebaum I had a discussion with Luc about that a while back. He said the standard doesn't guarantee thread safety on push/emplace-back for even a deque. Even if it is in all implementations.
So I had to do something customized.
It's an array of arrays. The first two arrays have size 1. The next has 2, then 4, then 8. All the way up to 2^64. (which is overkill btw)
Dereferencing an index on the vector involves doing an lzcnt/bsr on the index to determine which sub-array it belongs in. Then some bit twiddling to get the index within the sub-array.
@HubertApplebaum It made the index conversion easier.
@HubertApplebaum I can't say whether a queue would've been a point of contention since I designed it without a queue in the first place in the expectation that it would be a point of contention.
@HubertApplebaum I can't say whether a queue would've been a point of contention since I designed it without a queue in the first place in the expectation that it would be a point of contention.
In the asymptotic sense, anything that has a single-access point will never scale beyond a fixed number of tasks/sec O(1). Regardless of whether there are locks, the cacheline that holds the head of the queue will be bounced around all the cores. In a fully decentralized system, there is no single point of contention. So there is no limit to the number of tasks/sec except those imposed by the cache coherency protocol of the hardware.
@orlp This is for all threads in the system. Not just one core. So we're talking potentially hundreds of threads simultaneously trying to put work into the thread pool.
@Borgleader Not really. A lock gives a thread exclusive access to a region. But that's overkill. In reality all you need is to broadcast the fact that you're busy. And there's no limit to how many threads can read a memory location provided that nobody changes it.
bool ThreadWorker::try_dispatch(WorkerTask& task){
WorkerTask* null = nullptr;
// Optimization: In most cases, the thread will be busy. So let's break
// out early without the compare/exchange.
if (this->task != null){
return false;
}
// Now test it for real.
bool success = this->task.compare_exchange_weak(null, &task);
if (!success){
return false;
}
std::lock_guard<std::mutex> lg(lock);
cv.notify_one();
return true;
}
If load reg, B reads the 456, then the load reg, A is guaranteed to pick up the 123.
Because x86 guarantees that thread B will see the 123 before the 456.
In C++, this is implemented with std::atomic<void*> or whatever. Those will guarantee that behavior. On x86, it compiles to lockless load/stores since x86 guarantees write ordering.
Even after removing std::string, using std::map's transparent lookup, refusing to allocating memory until the very last moment, we're still SUPER in the fucking shitter for member function calls.
250 ms slower than everyone else.
And nearly 400 ms slower than fucking Selene.
Selene, of all things, the most offensive framework when it comes to performance.
And when I try to explain that on the lua mailing list, I get a bunch of meandering about C code being faster than C++ code, and I'm just so fucking done.
It IS my problem because other frameworks that aren't supporting member variable access (e.g., myinstance.a = 24) are getting away with it because they don't have to go through lua the same way I do.
So they get heaps of performance for fuckin' free.
And of course having lua provide me with the fucking thing that triggered metamethod lookup is just too goddamn hard.
"Hey, this is the thing that started this insane lookup cascade" nah nobody needs that fam, because why would you need performance THAT'S SILLY.
