The following answer is valid for VS2013 ONLY
What we have here is actually stranger than just memcpy vs. memmove. It's a case of the intrinsic optimization actually slowing things down. The issue stems from the fact that VS2013 inlines memcopy like thus:
; 73 : memcpy(store[i % 100], ...
you'll note that the comments make it pretty clear that just using std::copy is the best choice as it allows the library/compiler the most options to optimize the crap out of it
@SzymonMarczak if you actually peek into an implementation they use a lot of type traits to figure out what you're copying and if it's safe to do binary copies or not. The compiler can then always issue the best choice for what you're doing.
i have a question, when we do, for example, a fopen oof a file, are we loading the hole file to the memory if we open a non binary file, or are we justmaking a pointer to the begining of the file in the disk?
Also, why char a[8000000]; causes a crash? Just want to notice that char *a = new char[8000000]; (yes I remeber about delete[] a) doesn't crash. I'm getting Process finished with exit code -1073741571 (0xC00000FD) on MinGW64 on Windows.
the other thing that taught me was a few videos on exception safety, where it was basically pointed out that making new exception safe was extraordinarily painful. So don't use it.
@SzymonMarczak Falling down? Destroying element 1 destroys element 2 which destroys element 3 and so on. In theory everything gets destroyed properly no problem. In practice after calling enough destructors you run out of stack space.
That is what my example was trying to illustrate. You have something like struct Node { std::unique_ptr<Node> next; }; which produces a chain of elements. Then the first Node goes out of scope which causes a chain reaction which deletes all the Nodes.
The problem is that you keep calling the destructor of Node recursively which might eventually make you run out of stack, depending on how many elements you have in that chain.
The solution is usually to use a vector<Node> to store all the nodes and then use a regular dumb pointer for the next pointer. That way the Nodes are deallocated sequentially and not recursively which uses a fixed amount of stack.
@ratchetfreak Ok, I understand it, but it would be great if you could illustrate it :D (for example you would use it if you had to do ...?) Sorry if I'm bit annoying :P
This question attempts to collect the few pearls among the dozens of bad C++ books that are published every year.
Unlike many other programming languages, which are often picked up on the go from tutorials found on the Internet, few are able to quickly pick up C++ without studying a well-written...
int n = 42; int a[n]; // there, invalid C++, but gcc won't complain about it without -pedantic because it's a gcc compiler feature, doesn't matter that it won't work on Visual C++
@milleniumbug seems like a bug, as that's ill-formed IIRC in C++17
> This feature was briefly part of the C++14 working paper, but was not part of the published standard; as a result, it has been removed from the compiler.
@SzymonMarczak The right side is null terminated the left side is not. The point is that the right side says "The string ends when the first '\0' character is encountered" while the left side says "The string is exactly hello.size() long and it doesn't matter if and where '\0' characters are".
@Platus Even assuming that v.erase(it); didn't invalidate it (it does), this would be a terrible idea as a rule. To both make it work and make it substantially more efficient, start by finding the first non-zero item, then erase everything up to that point in one call.
This question attempts to collect the few pearls among the dozens of bad C++ books that are published every year.
Unlike many other programming languages, which are often picked up on the go from tutorials found on the Internet, few are able to quickly pick up C++ without studying a well-written...
I don't know about good tutorials for algorithms in C++, but that SO Q&A about implementing classic sorting algorithms in standard actually had good examples
The std::sort algorithm (and its cousins std::partial_sort and std::nth_element) from the C++ Standard Library is in most implementations a complicated and hybrid amalgamation of more elementary sorting algorithms, such as selection sort, insertion sort, quick sort, merge sort, or heap sort.
The...
I would like to compile my program with variables from an xml configuration file. What's the best way of doing this? I have thought of a 'pre-build' step to read the xml file and generate a header file which can then be included in the building of my program.
I don't want to do it at run time, for various reasons. I want to build my program with different configurations and just have the binary. I'll look into the preprocessor, but what about my suggestion about generating a header file separately beforehand from the xml file?
I also can't use any 3rd party libraries. For reasons that I can't get into.