There is a question "How is data structure useful? " and points that came in my mind include 1) Allows efficiently store data 2) which in turn allows a data value to be searched and found easily. what else can I add ?
it assumes us elite C++ coder snobs are running Winblows
of course, on the other hand, Linux is written in C
since Linux is in C and not C++, it's beneath us
I suppose we should all just roll our own operating systems
I'm sure I can encapsulate my hardware better than Microsoft did
and their style - no RAII, poor use of templating, etc...
I mean, I'm an elite C++ coder, so I'll make a realistic project assessment. how long to develop a replacement for the Linux kernel that is compatible with both it and Windows? I think I can have it done in 3 weeks with the power of C++
That is,
The Power of Syphilitic C++ (std's sprinkled everywhere liberally)
You know, I replaced the f1 key on my keyboard with an std:: one. Literally, it has std:: on it and when I press it, std:: is typed. I figured since I'm an elite C++ coder I never need help with anything, so the f1 key was just taking up space anyway
I mean, technically you can just do void *ptr = (void *)((intptr_t)myInt));
well, we've taken a value of an integer and put it into a pointer. then we've cast that pointer into a void type. we do that in reverse to "unpack" it.
int output = int(ptr);
that should work
let me see if it throws compiler errors, I'm currently causing MSVC to dump core with some metatemplates so hold on while I wait for it to stop
reinterpret_cast works fine, it's just dumb and ugly. what you're trying to do is really a C thing; reinterpret_cast<> is a C++ way of doing it. you can do it if you want to. there's functionally no difference that I know of
in the rest of the program, the unique IDs are being used instead of pointers to the game objects, as the game objects can be destroyed (and deleted) arbitrarily
it's difficult to notify the rest of the program (many different places) when something is deleted
and how many objects are requesting from this std::map all the time? like, let's say, do we have 5 different functions grabbing each pointer and working with it every frame?
well then, it strikes me that if you're having performance issues (or are expecting to), there's much better ways of doing it. but if it's performing well for you, they're not worth reimplementing a working system
hmm, well I don't know all the details, but I'd probably use an 'object pool' for each object type, basically a big array (or a few big arrays), from which I would allocate the maximum number of objects of that type
they would have a 'valid' or 'invalid' marker;
the void* would point directly at the valid or invalid marker
in order to handle insertions and deletions, I would use a separate hash map (std::unordered_set) to keep track of that memory pool
this would give things constant time access to pointers (instead of logn), and constant time insertion and deletion(since it's managed using a hash map)
but that's making an assumption about how your data flow goes
the tradeoff, of course, would be that iterating over an object pool could be a bit expensive, but I imagine that your object status object pools would fit in cache and wouldn't be much of a burden
/** converts 'WinMain' to the traditional 'main' entrypoint **/
#define PRO_MAIN(argc, argv)\
int __main (int, LPWSTR*, HINSTANCE, int);\
int WINAPI WinMain (HINSTANCE __hInstance, HINSTANCE __hPrevInstance, \
LPSTR __szCmdLine, int __nCmdShow)\
{\
int n...
I suppose I'd add a counter to it: every time it is deleted, the counter is incremented. if that object has the wrong count, it knows the objecti n the pool is invalid
well, it knows the object isn't the one it thinks it is
so now each object that has references to other objects also has to keep track of the "deletion counter" to make sure it is not referencing something else?
there are many interrelationships between the object classes, which is why it is so awkward to attempt to notify everything that could possibly be referencing an object in some way
@Datalore yes, but on the other hand each of the 5 times it accesses that object, it only has to do O(5) operations instead of O(5*logn + constant for structure that keeps it to figure it out)
and since objects can acquire the pointer to the unique ID they want, they don't need to even query a holder object - they can just take a pointer to the object with the unique ID and keep track of what they expect the destructor count to be. much shorter path to actual data
basically you replace a holder that takes O(logn) every time you want to look something up with something that lets you have direct access to your objects, look up IDs in constant time, and when 'holding' them, do 1 check on them (destructor_count == expected_destructor_count)
that seems like a significant burden on the programmer every time he/she wants to get the actual objects out of the identifiers
just a lot of awkward extra checks littered throughout code
there is another case where having the distinct unique identifiers is helpful; there are some instances where an object might be silently replaced with a proxy to it, which behaves in a similar way externally but is a different object entirely
those akward checks can all be replaced with a short, concise inline function, or if you're using OO style, inherited from a base class that provides that functionality
as far as proxies go, you can simply overwrite the data without updating the destructor_count
I could code up a short example in about 10 minutes if you're truly interested. if not, I should get to bed
another issue is that we have a system of essentially silently-replacing objects with other objects. not all IDs resolve to the same things at the same times; there are actual versions of objects (which are the full, real object) and intel versions (which have the same interface, but limited use, and are usually a copy of an old version of the object). that makes anything other than resolving IDs highly problematic
(i am the head designer, he is the head programmer, if the sudden addition of a new person clarifying things is confusing... ;) )
no, probably just didn't know it exists. needed something rather urgently to do that so i just shoved it in. if something else does that... well i feel stupid then
C++11, also formerly known as C++0x, is the name of the most recent iteration of the C++ programming language, approved by ISO as of 12 August 2011, replacing C++03. The name is derived from the tradition of naming language versions by the year of the specification's publication.
C++11 includes several additions to the core language and extends the C++ standard library, incorporating most of the C++ Technical Report 1 (TR1) libraries — with the exception of the library of mathematical special functions. C++11 was published as ISO/IEC 14882:2011 in September 2011 and is available for a fee....
haven't really been that many to make a conclusive argument. at this point it is less structure and more the fact we're stuck with what we have, lest all the drivers and higher-level components be replaced
linux barely gets by with drivers as it is, if hurd solved all its problems, it would still have issues unless it somehow managed to be completely compatible with linux drivers
BSD gets by, but if you go completely changing architecture, it probably won't last
I'm not going to stay up late debating if a microkernel is better than a macrokernel. micorkernels lost out to macrokernels; microkernels have had consistent and good development put into them for a long time and they still just suck. when that changes when they make magic fairy sprinkle dust that makes them perform decently, I'll change my mind
i programmed an incredibly confusing and ultimately pointless system of building comparison functions out of classes and function pointers. was more fun than practical in the end... i've never seen a binary that large
When I define this function,
template<class A>
set<A> test(const set<A>& input) {
return input;
}
I can call it using test(mySet) elsewhere in the code without having to explicitly define the template type. However, when I use the following function:
template<clas...
Imaginary syntax, of course, but the point is that it expands to something like this:
struct
{
template <typename T>
void operator()(T x)
{
std::cout << x << std::endl;
}
} __lambda;
There are 10,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000particles in the universe. your mother took all the ugly ones and shoved them into one nerd
someone in here wrote it, I can't take credit, I just love things that abuse compilers. it makes me want to make GCC dump core using a similar technique
but first I must know if it's just my machine that it dumps on
and I'm still compiling release, it dumped way before now in debug
I was honestly wondering what would happen if I used pointer indirection that wouldn't fit inside my cache
like, all the pointers to further pointers, being larger than my cache
I imagined it would make things horribly slow
I was going to do some simple math and benchmark it