The underlying structure is an array. And erase just move stuff around and changed the end location. So unless the reference/pointer is the end value I would think it would be defined behavior.
other threads are only guaranteed to observe the changes if they lock the same mutex, so they would have to ld.acq themselves to observe all the changes until the st.rel, right?
@PeterT What if another thread does ld.acq and enters CS before the other thread does st.rel?
I am confused. What is being stored into the mut variable?
I am trying imagine the mutex to be some sort of a flag indicating whether the lock is taken or not. So when it's taken, there should be a write marking it as taken before entering the CS. It's that write I am looking for.
oh, yeah. I don't think that's the "only instruction needed for the lock". It's the instruction guaranteeing the ordering part, but not the one guaranteeing the exclusive part
how can you print out an uint8_t ? So I have a array of pointers but want to print out the index(uint8_t) from the class. so I did this: for (size_t i{};i<3;++i) { std::cout<<pUSBarray[i]->index<<".\n"; }
@nwp Thanks for letting me know. This is not the prettiest chat interface I have seen lol. Not sure how to edit. But if it's not possible, that's still fine with this email.
An OOO processor can issue loads out of program order. The x86 memory model says reads are not reordered with reads. How do I understand this statement? Does that mean all later loads are dependent on current loads even if they access different locations?
I think I have misunderstood something. Not being able to reorder reads after reads implies that all loads are serialized which implies you can have at most one load-store unit and the scheduler should send loads in program order. I don't feel like this is how processors work.
Suppose there are two load-store units and you simultaneously issued two adjacent load instructions to the two units. What if the earlier load happens to be an LSQ miss and the later load happens to be a LSQ hit?
Will the load that had an LSQ miss block the load that had an LSQ hit just to ensure ordering of loads?
It also feels like this ordering requirement may hurt latency hiding capabilities. If there is an LLC miss, then all later independent loads would have to be stalled even if they could potentially be resolved via LSQ or L1 or from somewhere.
Hi, I tried to use std::chrono to measure the speed of my code.
code snippet:
auto start1 = std::chrono::steady_clock::now(); // add the new element to pUSBarray, between the second and third elements pUSBaddarray(pUSBarray, &USB3, 2); auto end1 = std::chrono::steady_clock::now();
std::cout << "Time taken for the pointer array: " << (end1 - start1).count()<<" .\n";
the problem is that this outputs and large number like 100. Not sure what is going on because on the cpp reference page it should output seconds not something big like that?
You need reference semantics for that, because Food arr[2]; tries to initialize the array with default values (which are abstract, thus not constructible).
I think std::array<std::unique_ptr<Food>, 2> arr; should be the most natural to use in this case.
std::array<std::unique_ptr<Food>> arr = {...
I was given a code, I understand it has a lot of weak points, e, g. the arguments could be not integers. Anyway, I know that the order of arguments to be pushed onto the stack is not defined in standard(the last argument can be pushed before the first one and vice-versa), so some compiler could push onto the stack first the variadic arguments and then the argument k and the program would try to reach some other data on the stack or just get a segmentation fault, am i right?
`int sum(int k, …) { int *p = &k; int s=0; for ( ; k!=0; k--) s+=*(++p); return s; }`
so if you pass in a vector you're planning to store as const& then you prohibit the caller from std::moving in a vector and saving allocations and copies
also when assigning member variables... do them in the initializer list and not the body of the constructor if possible to avoid double initialization
but to expand on the move thing... you can avoid copying the vector entirely if the caller is aware
foo(std::vector<bar> foobar): m_foobar(std::move(foobar)){} is a lot more efficient than what you're doing
also this is more efficient only because a constructor is a sink and is grabbing ownership
The way I understood it is that having a double ampersant, aka rvalue reference, is so that you don't have to have the const specifier in function signatures:
Hmm maybe this has something to do with "perfect forwarding"...
urgh cant edit anymore, but the second example where you pass the 10 as argument, should -obviously- not have the const specifier. Should just be void fnc(int&& x)
@LandonZeKepitelOfGreytBritn the real question is "why would not needing the const be helpful?" - it's not about somehow reducing stress on those 4 keys on the keyboard
Do you know what an rvalue reference means? Or rvalue, for that matter? Because that's the key. When you ask "what does T&&" mean, going by "what other thing now changes" is indirect, There are absolute, direct answers (multiple, because T&& means different things depending on context)
@sehe the way I understood it: an rvalue is a-n intermediate- value which is actually not stored anywhere explicitely, eg: int y = 5. If you however were to have int y = x, you actually have 2 lvalues. Now the rvalue reference is actually a feature which allows you to have the address of that (unstored) intermediate value. By doing: int x = 5; int& y = x; you created an alias for x of type int& and y is now an alias for x thanks to the underlying dereferencing
@sehe the added value of a reference is that you can pass it as an argument to functions and that it cannot be NULL, which in turn alleviates the need for defensive coding patterns where you check for nullptr and also does not lead you to undefined-behaviour-land
that s the benefit of a reference, not the benefit of a reference to a temp though...
@LandonZeKepitelOfGreytBritn I think you are putting too much stock in "references are addresses". That's not actually relevant.
The key is "move semantics". By having a reference that is "qualified" as an rvalue-reference the compiler is allowed to move from them (as, logically rvalues weren't going to be used after the fact. say:
Rvalue reference would be worth NOTHING without move semantics. Move semantics are to avoid this very very typical pre-c++11 pattern: godbolt.org/z/9aGshE5aY
Here first a temporart string is constructed for the argument, which is then **copied** to the member variable. Then the temporary is destructed. Actually this used to be a painful downside from being the language with value-semantics all around: for really performant code you sort-of **had** to use dynamic allocation a lot to avoid ineficient cases like with these absolutely common vocabulary types.
Since C++11 you can take the string by value and std::move() from it, replacing a copy with a move, which can often be equivalent to just copying a member pointer(s). Effectively, you can /write/ value semantics and the compiler can /emit/ the optimized code.
Now, there are two kinds of caveats:
1. taking std::string&& signals to the caller that the receiver intends to (potentially) move from the argument, but to do so, it must still tell the compiler again with std::move (godbolt.org/z/n9fWrdTsE)
@sehe Still reading on the matter as we speak, but long story short: rvalue referencing leads to move semantics, while const T& leads to copy semantics. Right?