Hi all. I'm currently looking at value categories in C++ and I think I'm able now to differentiate xvalue, lvalue and prvalue. But I'm not sure to understand in what case it can be useful to make this differentiation. Do you have any example where it is important, as a developer, to make the distinction between value categories? Thanks.
It isn't. You only need to make this differentiation if you want to write a C++ compiler. Programmers only need to know what a temporary is, why it matters and how to force a non-temporary to be treated as a temporary.
Just use values where possible and reasonable and smart-pointers where it's not. That covers 99% of you memory management needs
We have a bunch of ruby and JS developers in our company that contribute occasionally to a C++ code-base, they don't run into any horribly memory management issues. Because the code-base is new enough that you won't find any "new" or "malloc" in it
@JBis just to be clear the "they manage their memory" goes for value types you put in those containers, if you put raw-pointers in containers, then the container won't clean them up
@Yashas Yes, OpenSSL infamously used to do this... and then it had an incident where the compiler detected it and did time travel because it's UB... causing hundreds of certificates to need to be regenerated
@JBis do you need C++ for what you want to do? or can you do it in JS just fine? Unless there is a massive performance need you can actually optimize your JS pretty well
@Mgetz idk, I probably don't need it. But I'd like to learn some new langs. And C++ isn't going anywhere. I will probably also learn Kotlin eventually.
allowing the useless computation to actually happen is faster (anyway the these are going to be predicated instructions regardless and will consume cycles)
@Yashas so how uninitialized is it? E.g. where are you allocating it? Because it could be live from a kernel perspective even if it's dead from a C++ perspective
@nwp The synchronization barrier in the loop prevents the compiler from unrolling properly. This is probably correct behavior but by my logic I know that you can mix computation across the barrier. So I have explicitly unrolled in a way that I compute first half of the loop body for N iterations and then do the second half of the loop body for N iterations. The compiler is unable to do this.
@Mgetz group_i_boxes and group_i_size have uninitialized memory.
@JBis Depends on how it's used. If you make a matrix class and provide the usual arithmetic operations then it's fine. If you add operator<< to your class so you can do std::cout << myclass; it's also fine. If you start creating your own language by defining that f | g means the the function f is executed and then g is called with the result then it starts getting not so fine.
but an array like that the object lifetime starts when the array is declared, technically constructors of complex objects are supposed to run. en.cppreference.com/w/cpp/language/lifetime
@Mgetz Oh my, I remember that {} syntax. I instead moved the block stride loop condition inside the body and wrote zeros when false.
I don't think the compiler will be able to optimize that to what I have done though.
Probably zeros the whole memory and then again populates it.
For the grid dimensions I have, the zeroing is completely useless most of the time. Only the edge bocks actually do not fully fill up the shared memory.
I have 10 users on my server. They often logged in to my server, but I can detect when they logged in, which user logged in. If it is alright with you guys, please tell me.
Or put in a way which scares the CPU programmers, CUDA shared memory is a cache where you manually control what is stored where. It is just a special addressable memory backed by fast on-chip memory but I don't like this description because it doesn't sound as scary as "user-controllable caches".
JS devs are going to have a hard time writing C++ code. You're going to find stuff that obviously should work (at least works in JS) not work in C++. I blame JS though for have ridiculous features stuff that murders code readability and unnecessarily complicates things. I like C++.
@JBis I used to write basic C++ code since high school. I found JS super frustrating while learning in uni. It's so evil! I thought C++ was a very complex language but then I found JS! I felt like C++ has complexity but the complexity offers performance benefits or other advantages but JS complexity felt completely unnecessary.
I might be biased as I like C and C++ very much (and usually end up in fights defending C++ while arguing with python-ers and webdevs). I am also a n00b at C++ and JS and might not be able to see the overall picture. Should take whatever I say lightly.
@Yashas you'll enjoy TypeScript a lot more probably. I struggle with larger programs in dynamically typed languages, seems so insane that people actually do that
@JBis The compiler you wrote seems to just be a lot of copy/paste. From a language feature point of view I'd expect the calculator to be more complicated.
1. My error throwing doesn't seem to work. Why is it such a PIA to concatenate a char to a string? How do I create the prop exception? 2. My IDE/clang is complaining about `getCurrentValue` saying it should be `const` and `no discard` so :
[[nodiscard]] int getCurrentValue() const {
return this->current_value;
}
@JBis ask yourself the likelihood of this happening and what should happen when it does? Is this something the caller should be able to restart? Or is this something that needs higher level cleanup and handling?
@JBis [[nodiscard]] because C++ doesn't give warnings that you're calling a method that the only valid reason to call it is to get a value. const so you can access that method on a const instance or reference as it doesn't modify and is safe
@JBis That's extremely expensive for an expected failure
@JBis actually what it says is that it's safe to call via a const ref or constant instance. Generally speaking that means it doesn't modify anything. That matters because using const correctly stops a lot of bugs. It's using the type system to help you
const is part of the C++ type system. const int is not the same as int
int &num - reference to arg, i'll probably modify num
int num - value of arg, i'll probably modify num
const int num - value of arg, i'll won't modify num
const int &num - why do i need the reference if i am not going to modify it?
oh wait i may know the answer
If it isn't int, but an instance of a class say Foo. Then I would need const Foo &foo because I wouldn't want to clone the instance?
that said doing things like foo bar for an argument has value because it allows either in place construction possible in the argument list or for someone to std::move something inside
so sometimes when you need a copy of an object, you will intentionally not take a reference (this also has some nice properties from an exception safety perspective which you will understand when you start learning this topic)
:49799361
// expects a copy of str
void do_something(std::string str) { /* ... */ }
std::string abc = some_other_string or you initialize it with something;
do_something(std::move(abc)); // abc is not copied but instead moved
// abc is no more valid
without the std::move, abc will be copied => you might potentially have to allocate memory to store a copy of the string (std::string can store strings of arbitary length using dynamic memory)
but you will have situations when you know that you don't need abc anymore, so you directly move it in and save a copy
sometimes as a library writer, you won't know what kind of inputs users will pass. You have to write code that takes care of the worst case scenario like 1GB vector!
@Mgetz Basics. Pointers point to an address in memory with an associated value. A reference copies a pointer to a different name. The before name and the new name reference the same value in memory so if one changes the other changes (because they refer to the same thing).
I don't think "A reference copies a pointer to a different name" is accurate. A reference always points to an object. It can never be null. Pointers can be null.
There are other differences when you use them as function parameters. You cannot pass a temporary object to a function that accepts a pointer (because you can't take the address of a temporary) but you can pass it to a function that accepts a const reference.
@Mgetz Sorry, here's more context. This is a part of code that is meant to read bytes in a certain layout from memory into a struct, or a tuple of variables, in other words.
@Mgetz I understand that. What I wonder about is, well.. this looks too low-level for a codebase written in C++? Or is this how this is done in production code?
There are a couple levels of segmentation involved, you know, groups of segments, then segments themselves, etc.. so there is something to watch after, indeed.
To sump up what we got so far. Option 1. Protobuf. Option 2. Leave `#pragma pack` be as it is right now. Option 3. ? (probably the one I was looking for, if it exists)
@Mgetz that would be the case when reading from the file directly, however, there are couple levels of segmentation (and defrag) involved. It's simple and linear, but it's there.
The code is written in C-style, not really portable C++. I'm updating, fixing it to match the protocol, etc.
@PeterT Not sure I understand the question honestly?
I mean, when stuff is in a memory buffer already, we can't use ifstream::read, can we? There has to be a different kind of istream for that? Sort of like stringstream, but a binary one.
@Mgetz Just to make sure: this code implements a parser, thus its behavior entirely depends on the input. Are sanitizers able to detect the kind of errors I'm looking for statically, without input data?