@JoshMenzel I noticed that. First I was planning on getting rid of allocations in the Message implementation (and perhaps making things more typesafe/convenient). But you know how it went already
@JoshMenzel My rationale here was that doing a thousand weak_ptr::lock() may take signifiicant time. I was a bit hesitant about the latency introduced by posting 1000 extra tasks first, but at least they get out of the way of timedBcast
Partially. Actually, the lock() is what checks weak pointers, so it replaces the need to synchronize on removal of dead connections. The other win was no longer having to synchronize manually on `connections` because all the access is from the `Server::strand_`
@JoshMenzel Yeah, it's not highlevel. But it's bread and butter in context of strands, I suppose, because often you need to force some work to happen on a strand
The first changes were very typical: reduce allocation, do less work. This step is not very typical (trying to reduce lock contention and increase concurrency).
I feel I have to point out once more that I think the timing numbers are way too flattering. You actually only time the dispatch of tasks, no longer reflecting any true latency - but it will sure be there (if only in the post to another thread).
@JoshMenzel I think you're just less good at patience, but make up for it with quick mind and good research.
Keep in mind, some of these coping strategies are based on experience; they will never come with ease. Not everything can be taught in tutorials because it all comes down to the nitty gritty details, the bytes and threads.
Do you remember how much time I took just reading through until I could piece together a story of how the access/usage patterns would be? That took hours.
@JoshMenzel You're always constrained. There is no silver bullet.
Locks haven't "gone away" either. It's just that we can entrust the library with them (they're hidden in the strand execution service implementation details).
The idea is that (a) they'll have the scalability figured out (they do). (b) they can make all kinds of smart decisions, taking advantage of the fact that locks are not acquired during async tasks (blocking the pool) and they happen on edges between tasks, and the scheduler can take into account (e.g. when continuations are already on the same strand, I imagine).
@JoshMenzel It does pretty much literally what you had, except it comes with robustness.
You should check the documentation for the default number of threads (ISTR it was 2*hardware_concurrency` when avaikable, but haven't checked). That's another thing: hardware_concurrency() isn't guaranteed to run useful info. It may legally always return 0 on a platform.
In a thread which has not ever called and would never callasio::io_context.run(), must I invoke post()dispatch () to dispatch tasks to the thread which has called asio::io_context.run()?
In a thread which has not ever called and would never call asio::io_context.run(), must I invoke post() or dispatch() to dispatch tasks to the thread which has called asio::io_context.run()?
Is it safe to directly call asio::async_write() or asio::async_read() in a thread which has not ever called and would never call asio::io_context.run() to dispatch tasks to the thread which has called asio::io_context.run()?
The "but" is that you're responsible for thread safety/synchronization. E.g. a tcp::socket object is not thread-safe. You should only call methods on it from one logical thread (e.g. strand) or critical section (e.g. using mutual exclusions, mutex)
In a thread which has not ever called and would never call asio::io_context.run(), must I invoke post() or dispatch() to dispatch tasks to the thread which has called asio::io_context.run()?
That's basically how that works. Yes, it's also a "cheap" way to implement a task queue (see e.g. stacko...
Next time, please consider linking to your question if you posted on the main stie
Hii , everyone. I am a new learner in C++ & am learning about binary number system rn.
I really need your help since I am not able to understand why it is used. Mostly , online I have read that since switches have only 2 buttons , ON & OFF. We use BNS.
But I want to Q that in a computer , it is said that everything which is working inside of it like apps . They are all binary. Then , when we talk about alphabets having BNS. I read that t is represented as 01110100. So , what does this mean.
Due to how computers are built they can only represent on and off in their flipflops. Then you use those to make registers and end up with a number of bits (64 for example). And now you have to figure out how to represent a "t". All you have is a bunch of bits, so you assign some arbitrary bit sequence to represent it.
The knowledge that 01110100 is supposed to be a "t" has to come from outside. Usually in programming languages that knowledge is represented as a type.
Ok. So , it is our choice to assign 0 or 1 as off or on. In reality , we can do anything with them. Like you wrote. We can assign a variable ‘t’ a value in binary. Is this right what I’m typing ?
Also , I also studied about quantum computers & ternary computer. In them , you can store value with more than 3 logical states & even more in quantum especially
Mostly. For example that t is that number is because of the ascii table which I believe is part of some standard, so deciding that you want some other number to represent t will be tricky, but basically yes, it's arbitrary.
so a ternary computer is still just a binary computer such that the logic is built around the value 3. Quantum computers aren't computers in the same sense at all. They are their own thing
Ok. Interesting. Thnx a lot. I really enjoy this discussion & which actually tells my gut to explore more of computer science. The problem in schools is that we do know how to code but don’t understand what is happening inside & how can this be used in future.
That's a bit of a personal preference. Some people like to know which current goes through where when they write an instruction. Others do CreateWindow and don't care how it's done, they just want a window.
It may not be as you’re saying but I think that unless you don’t know what is happening inside. The subject actually doesn’t give much of a feel. For example , in my case. If there could have been a simple practical experiment to show what the textbooks mean to say or a animation so as to understand what is happening.
@Electrical_engineer_student what do you mean by "is getting skipped", just "returns immendiately? If so then you already had something in stdin when you arrived at that code
reply to PeterT: getting skipped means it is not waiting for the user to press enter and asking for the upper bound straight away.
I used cin.clear() but that does nothing. While debugging, the "enter the lower......" line does not wait for the user to input anything and goes on straight to the upper bound line but then stops there(which it should). But why is it not stopping at lower bound part?
@JoshMenzel Like I said yesterday, quite the opposite! By value everything, please. Less aliasing, less sharing, less locking, less head-aches. However, in this case you had an immutable message that was a going to be replicated to literally thousands of connections.. so that totally calls for §std::shared_ptr<Message const>§
@JoshMenzel Yeah if you wanted to share the object. However to manage the lifetime you needed more. Of course, you can try to garbage collect. But I'd use allocate_shared with a pool allocator before that.
`T` - by value, `T (const)&` by ref `T (const)*` by raw (non-owned) pointer, nullable `unique_ptr<T>` owning pointer (move-only, as in can't copy) `shared_ptr<T>` owning pointer (refcounting) `weak_ptr<T>` non-owning observing shared pointer
@JoshMenzel It's where everyone goes wrong the most because it's one of the sole reasons to use C++. Value semantics by default makes for high level of control.
(by the way, I think if you surveyed c++ programmers, less than 1% would know about allocate_shared, likely)
@JoshMenzel It's talked about all the time. It's just that most people don't "get" it when they hear it. They're usually full of assumptions coming from other languages. It takes time to even notice that there are microbes in your drinking water, let alone pay attention to herding them :)
If you take a random sampling from c++ questions I bet that >60% is about value/ref semantics in some way shape or form.
@JoshMenzel I'd say, rely on yourself. You have to build and trust your own understanding. Use tools (asan,ubsan,tsan; valgrind) to spot when you're making a lifetime error, which will often go unnoticed until they crash (or launch the nuclear missiles).
This is never going to come from tutorials. It's like people who want to become great at chess by reading a book. Or multiple books. They're never going to get there.
If you keep sharpening the axe - as you quite clearly already have done for a long time - one day you'll find yourself either just seeing optimal plans or improvements, or having the trust and calm to attack problems with your tools (a profiler!).