A circular buffer, cyclic buffer or ring buffer is a data structure that uses a single, fixed-size buffer as if it were connected end-to-end. This structure lends itself easily to buffering data streams.
== Uses ==
The useful property of a circular buffer is that it does not need to have its elements shuffled around when one is consumed. (If a non-circular buffer were used then it would be necessary to shift all elements when one is consumed.) In other words, the circular buffer is well-suited as a FIFO buffer while a standard, non-circular buffer is well suited as a LIFO buffer.
Circular buffering...
I know lockless circular buffers are common knowledge. But I don't know which implementation details of our implementation are common knowledge vs. proprietary.
@Mysticial I don't understand - the implementation I linked does the same amount of work as an implementation that is non-threading, except with proper memory ordering
unless you want to go into architecture specific memory ordering/barrier options, this is as optimal as it gets
Here's a piece of advice: Open-sourced implementations are not always the best implementations. Sometimes, the proprietary stuff can actually better. (in this context, better == faster)
Heads up: we will be doing a failover of all services to our DR data center tomorrow to prep for network maintenance. http://stackstatus.net/post/126135656099/data-center-failover-august-8-2015
The MESI protocol (known also as Illinois protocol due to its development at the University of Illinois at Urbana-Champaign) is a widely used cache coherence and memory coherence protocol. It is the most common protocol which supports write-back cache.
== States ==
Every cache line is marked with one of the four following states (coded in two additional bits):
Modified
The cache line is present only in the current cache, and is dirty; it has been modified from the value in main memory. The cache is required to write the data back to main memory at some time in the future, before permitting any...
@Mysticial I certainly believe you. The most advanced open-source code I've found comes from Folly (Facebook) and the Intel DPDK library. I wonder how they compare with the commercial ones.
@Mysticial the reason I'm skeptical about you saying your propietary implementation could be better is simply because I don't see the opportunity for optimization in the generated code for the example I gave above - I never meant to claim in general that open source is always better
Thing is that boost libraries are intended for general-purpose. I often find that in order to make things fast you need to tune it for very specific use cases.
we can refer to something as 'your blablabla' where the 'your' does not imply ownership or authorship, but merely the thing that was introduced into the conversation by you
@StackedCrooked It's in house. And based on the file names, there's been at least 2 or 3 previous versions of it that are no longer in use and deleted.
Then I realized that having a templated class that creates a variable wrapped in a class that used decltype() to derive a specific templated type would be nice.
I don't like your method of doing it because it's too long and messy.
If I were you, I'd set up an associative map between string input and types, and then pass the types to the template once you've correctly converted from input to type.
Unfortunately, because you cannot play directly with typ...
Is it possible to store a type name as a C++ variable? For example, like this:
type my_type = int; // or string, or Foo, or any other type
void* data = ...;
my_type* a = (my_type*) data;
I know that 99.9% of the time there's a better way to do what you want without resorting to casting void po...
@unordered_meow Can't you do something where you have a factory class that returns a smart pointer to the type you gave its template and then wrap that in a wrapper class?
So it can be used in a vector/container with a uniform type?
@unordered_meow I mean, can you do something like allocator<decltype(a)>? with having type equvivalence in terms of templates when you place it into std::vector<allocator_wrapper>?
@VermillionAzure So you want to have an allocator<decltype(a)>, and push it into vector of allocator_wrappers.
Now you have two problems
One, you don't have mappings between external entities (the strings) and the internal entities (position of the allocator_wrapper in the vector, variables, types, templates, what have you)
Two, allocator_wrapper has one return type
Also congratulations, you reinvented std::function