It's not related to some specific kind of food. I guess that when my stomach is full it doesn't play well with my lungs and for some reason I have asthma.
It's the worst kind since it usually lasts a full day.
Out of curiosity, why does it often take seconds to obtain network configuration via DHCP when the CPU is capable of processing millions of operations per second and ping to the router takes a couple of milliseconds?
In my home environment with one WiFi router and about 5 devices, it is not rare...
how do we know you are not a mutant? for all I know you could be a giant mutant carp with fingers sending all those messages from a waterproof PC in a muddy river
@StackedCrooked Nice, Ive been meaning to try all of TBB by Intel, but I havent taken the time so far (mostly because I dont have anything on which it would be worth using)
> This is because jemalloc's only sense of time has been in terms of allocation events, thus precluding work postponement. This talk will provide an overview of jemalloc internals, critically analyze several past approaches to cache management, and describe multiple opportunities enabled by wall clock awareness.
@Borgleader The tbb::concurrent_bounded_queue can serve a broad range of purposes.
The real power of tbb is in their task scheduler. For which unfortunately I haven't found a good use case yet.
General purpose lock-free queues are so complicated that you should never try to implement them. Implement something specific to your application requirements.
std::queue + spin-lock is sometimes faster than lockfee queue.
Because lock-free queues manipulate multiple atomic variables (head, tail) using compare and swap.
And spinlock requires only one atomic variable.
I'm starting to think "lock-free" is the hoax of the decennium :)
The transformations needed to make it vectorizable are one of the cases that grows O(N^2) in code size to the SIMD width among other things.
N^2 with my current method. If things get any larger, I'll need to start playing with methods based on parallel-prefix sum the Kogge-Stone adder used in hardware.
Not only do you quickly run out of registers, but there's only one execution port that can do data-shuffling. And if the transposition is too large, the CPU's OOE won't be able to overlap the shuffling with actual computation.
And it all goes downhill from there. Especially in cases where you also need N memory access strides.
Give it a few more generations. I'm interested to see how far Intel can go with SIMD. Since they seem to have every intention of making it as wide as a GPU.
Obviously, you're also gonna need the programmers to keep up. But you kinda already need specialized programmers to fully utilize a GPU.
@Mysticial One guy from the company researched for about a year and did the job.
@Mysticial Interesting.
A brute-force threaded solution might also work. Suppose you receive packets that can have 30 different possible destinations. Then you could dump all packets on a ring buffer and have 30 consumers. Each consumer simply scans for its type of packet.
Based on what I'm reading, AVX512's gather/scatter in Skylake will not be at that point.
Suppose you have data that's stored AOS, and you need to load it into registers as SOA, there are two (obvious) ways to do it. O(N) gather-loads. Or O(N*log(N)) shuffles.
Intel's docs imply that the latter is at least twice as fast as the former for either Skylake and/or Knights landing with AVX512.
And to be fair, the silicon needed to make a gather/scatter efficient is not trivial.
@StackedCrooked It isn't. But Intel has already released a number of programming guides for it. And they explicitly recommend doing in-register shuffling over gather/scatter.
If you went with 4 gather-loads, it'll take much longer since gather-loads are probably around 10 cycles on Haswell? IIRC
@StackedCrooked If you have all 4 of them in the same vector, they can't talk to each other since vector operations only work vertically. (with few exceptions)
If you had to calculate a TCP checksum in software. Would you use special tricks like prefetching with hints on how long the data should stay in cache?
@Mysticial Actually I think currently context switching is a major bottleneck.
Depending on how the packet gets written into memory, there might be some other things to tweak. But they're probably so obvious that it's already been done.
Yesterday I discovered I made a huge mistake. I misunderstood my own async code. The result was packets were being processed and being overwritten with new data form the network at the same time.
This leads to weird results.
Like everything is perfect. But one packet in a millions has a wrong checksum.
@StackedCrooked Avoid copying. Also, IIRC, some OS did split their packets processing and passes the header and the payload separately. Thus header copying does not involve payload copying.
Switching circuit theory is the mathematical study of the properties of networks of idealized switches.
Such networks may be strictly combinational logic, in which their output state is only a function of the present state of their inputs; or may also contain sequential elements, where the present state depends on the present state and past states; in that sense, sequential circuits are said to include "memory" of past states. An important class of sequential circuits are state machines. Switching circuit theory is applicable to the design of telephone systems, computers, and similar systems.
In...