I am new to c++ as well as smart pointer.
I have a code like this.
Example* Example::get_instance() {
Example* example = new Example();
return example;
}
I am trying to convert it to smart pointer like this
shared_ptr<Example> Example::get_instance() {
shared_ptr<Example> example (new Example());
return example;
}
Is this the correct way because when i am trying to call this from another class its not working.I am trying to implement a singleton object.
You are creating a new Example object every time the object is requested, That is a memory leak, an you are also returning a different object every time. Try this instead:
Example & Example::get_instance() {
static Example example;
return example;
}
Also please note the following advices for your code:
when creating smart pointers prefer make_shared instead of shared_ptr<YourType>(new YourType(...)). The reason why can be found here. Relevant excerpt:
This function typically allocates memory for the T object and for the
shared_ptr's control block with a single memory allocation (it is a
non-binding requirement in the Standard). In contrast, the declaration
std::shared_ptr p(new T(Args...)) performs at least two memory
allocations, which may incur unnecessary overhead. Moreover,
f(shared_ptr(new int(42)), g()) can lead to memory leak if g
throws an exception. This problem doesn't exist if make_shared is
used.
understand the difference between std::unique_ptr and std::shared_ptr. For your case, a std::unique_ptr would have been better, but there is an even simpler solution to your problem, which I have shown above.
in general, avoid pointers when you can use references instead, they're easier to use and code looks a bit cleaner.
and finally, do you REALLY want a singleton? I just have to be ask. I've been working full-time as a programmer for almost 4 years now. Not that long, I know, but enough to have encountered the situation where I regretted that I or someone else used the Singleton pattern instead of passing the reference to my object down the call chain.
Try to avoid singletons, you may later find your code using the singleton might in the end want to work on multiple instances of your Example object instead of calling Example::get_instance and only work on that single instances. So when you'll have that revelation, (and it might be only a matter of time), you'll have major refactoring ahead of you.
So, "Beware, there be dragons!".
Related
I have inherited a pile of C++ code, saturated with std::shared_ptrs, most [all?] of which are unnecessary and are, I suspect, degrading performance. It is not feasible to change everything in one go, so I'm changing the code in tranches and doing performance tests.
An issue I'm running into is the interface in the method hierarchy between my new "raw" pointer code, and the underlying shared_ptr stuff. A contrived example (I know it could be simplified...):
SomeObject *MyClass::GetSomeObject(const std::string& aString)
{
//for the underlying shared pointer methods
std::shared_ptr<std::string> tmpString = make_shared<std::string>(aString);
//call the method using my local shared pointer
std::shared_ptr<SomeObject> someObj = GetTheObject(tmpString);
//The line below gives compiler warning: "The pointer points to memory allocated on the stack"
return someObj.get(); // a pointer to an object in std::map
}
I know that GetTheObject() is returning a pointer to an object in a persistent std::map, so that memory will be in good standing after we exit GetSomeObject() and the shared pointer [and its wrapped raw pointer] have gone out of scope.
I'm not in the habit of ignoring warnings, SO:
Questions:
Is the warning because the compiler is worried about the scope of the shared pointer rather than the object pointed to? [i.e. could I ignore it in this instance?]
If it is a real problem, are there any neat ways around this (that do not involve building wrapper classes and such workarounds...) ?
If I understand you correctly, you're replacing smart pointers with dumb pointers, in 2021, and you're now facing the exact problem that smart pointers intended to solve.
The warning is 100% accurate, and I'm pleasantly surprised the compiler looked deep enough.
The solution is simple: return a shared_ptr<SomeObject>. If you want efficiency improvements, there are two real improvements possible. C++11 introduced move constructors, and moving shared_ptr is faster than copying. The compiler will use the move ctor for return someObj; since someObj goes out of scope
Secondly, shared_ptr is a heavy-weight alternative to unique_ptr. At times, you may be able to downgrade to the latter.
I have similar code in my project. I agree that the proper solution is probably just to commit fully to the smart pointers and use them properly. However, I don't want to churn through piles of perfectly functional code, but I also want the warnings to go away. I was able to work around the warning with something like:
SomeObject *MyClass::GetSomeObject(const std::string& aString)
{
//for the underlying shared pointer methods
std::shared_ptr<std::string> tmpString = make_shared<std::string>(aString);
//call the method using my local shared pointer
std::shared_ptr<SomeObject> someObj = GetTheObject(tmpString);
SomeObject *pRet = someObj.get();
return pRet; // a pointer to an object in std::map
}
I'm a little worried that at some point the compiler will get smarter and detect that as a warning as well, but it seems OK for now. (Visual Studio 2022 v17.1) Hope that helps!
I am trying to write a simple game using C++ and SDL. My question is, what is the best practice to store class member variables.
MyObject obj;
MyObject* obj;
I read a lot about eliminating pointers as much as possible in similar questions, but I remember that few years back in some books I read they used it a lot (for all non trivial objects) . Another thing is that SDL returns pointers in many of its functions and therefor I would have to use "*" a lot when working with SDL objects.
Also am I right when I think the only way to initialize the first one using other than default constructor is through initializer list?
Generally, using value members is preferred over pointer members. However, there are some exceptions, e.g. (this list is probably incomplete and only contains reason I could come up with immediately):
When the members are huge (use sizeof(MyObject) to find out), the difference often doesn't matter for the access and stack size may be a concern.
When the objects come from another source, e.g., when there are factory function creating pointers, there is often no alternative to store the objects.
If the dynamic type of the object isn't known, using a pointer is generally the only alternative. However, this shouldn't be as common as it often is.
When there are more complicated relations than direct owner, e.g., if an object is shared between different objects, using a pointer is the most reasonable approach.
In all of these case you wouldn't use a pointer directly but rather a suitable smart pointer. For example, for 1. you might want to use a std::unique_ptr<MyObject> and for 4. a std::shared_ptr<MyObject> is the best alternative. For 2. you might need to use one of these smart pointer templates combined with a suitable deleter function to deal with the appropriate clean-up (e.g. for a FILE* obtained from fopen() you'd use fclose() as a deleter function; of course, this is a made up example as in C++ you would use I/O streams anyway).
In general, I normally initialize my objects entirely in the member initializer list, independent on how the members are represented exactly. However, yes, if you member objects require constructor arguments, these need to be passed from a member initializer list.
First I would like to say that I completely agree with Dietmar Kühl and Mats Petersson answer. However, you have also to take on account that SDL is a pure C library where the majority of the API functions expect C pointers of structs that can own big chunks of data. So you should not allocate them on stack (you shoud use new operator to allocate them on the heap). Furthermore, because C language does not contain smart pointers, you need to use std::unique_ptr::get() to recover the C pointer that std::unique_ptr owns before sending it to SDL API functions. This can be quite dangerous because you have to make sure that the std::unique_ptr does not get out of scope while SDL is using the C pointer (similar problem with std::share_ptr). Otherwise you will get seg fault because std::unique_ptr will delete the C pointer while SDL is using it.
Whenever you need to call pure C libraries inside a C++ program, I recommend the use of RAII. The main idea is that you create a small wrapper class that owns the C pointer and also calls the SDL API functions for you. Then you use the class destructor to delete all your C pointers.
Example:
class SDLAudioWrap {
public:
SDLAudioWrap() { // constructor
// allocate SDL_AudioSpec
}
~SDLAudioWrap() { // destructor
// free SDL_AudioSpec
}
// here you wrap all SDL API functions that involve
// SDL_AudioSpec and that you will use in your program
// It is quite simple
void SDL_do_some_stuff() {
SDL_do_some_stuff(ptr); // original C function
// SDL_do_some_stuff(SDL_AudioSpec* ptr)
}
private:
SDL_AudioSpec* ptr;
}
Now your program is exception safe and you don't have the possible issue of having smart pointers deleting your C pointer while SDL is using it.
UPDATE 1: I forget to mention that because SDL is a C library, you will need a custom deleter class in order to proper manage their C structs using smart pointers.
Concrete example: GSL GNU scientific library. Integration routine requires the allocation of a struct called "gsl_integration_workspace". In this case, you can use the following code to ensure that your code is exception safe
auto deleter= [](gsl_integration_workspace* ptr) {
gsl_integration_workspace_free(ptr);
};
std::unique_ptr<gsl_integration_workspace, decltype(deleter)> ptr4 (
gsl_integration_workspace_alloc (2000), deleter);
Another reason why I prefer wrapper classes
In case of initialization, it depends on what the options are, but yes, a common way is to use an initializer list.
The "don't use pointers unless you have to" is good advice in general. Of course, there are times when you have to - for example when an object is being returned by an API!
Also, using new will waste quite a bit of memory and CPU-time if MyObject is small. Each object created with new has an overhead of around 16-48 bytes in a typical modern OS, so if your object is only a couple of simple types, then you may well have more overhead than actual storage. In a largeer application, this can easily add up to a huge amount. And of course, a call to new or delete will most likely take some hundreds or thousands of cycles (above and beyond the time used in the constructor). So, you end up with code that runs slower and takes more memory - and of course, there's always some risk that you mess up and have memory leaks, causing your program to potentially crash due to out of memory, when it's not REALLY out of memory.
And as that famous "Murphy's law states", these things just have to happen at the worst possible and most annoying times - when you have just done some really good work, or when you've just succeeded at a level in a game, or something. So avoiding those risks whenever possible is definitely a good idea.
Well, creating the object is a lot better than using pointers because it's less error prone. Your code doesn't describe it well.
MyObj* foo;
foo = new MyObj;
foo->CanDoStuff(stuff);
//Later when foo is not needed
delete foo;
The other way is
MyObj foo;
foo.CanDoStuff(stuff);
less memory management but really it's up to you.
As the previous answers claimed the "don't use pointers unless you have to" is a good advise for general programming but then there are many issues that could finally make you select the pointers choice. Furthermore, in you initial question you are not considering the option of using references. So you can face three types of variable members in a class:
MyObject obj;
MyObject* obj;
MyObject& obj;
I use to always consider the reference option rather than the pointer one because you don't need to take care about if the pointer is NULL or not.
Also, as Dietmar Kühl pointed, a good reason for selecting pointers is:
If the dynamic type of the object isn't known, using a pointer is
generally the only alternative. However, this shouldn't be as common
as it often is.
I think this point is of particular importance when you are working on a big project. If you have many own classes, arranged in many source files and you use them in many parts of your code you will come up with long compilation times. If you use normal class instances (instead of pointers or references) a simple change in one of the header file of your classes will infer in the recompilation of all the classes that include this modified class. One possible solution for this issue is to use the concept of Forward declaration, which make use of pointers or references (you can find more info here).
I've read a reasonable amount in decent textbooks about the auto_ptr class. While I understand what it is, and how it gets you around the problem of getting exceptions in places like constructors, I am having trouble figuring out when someone would actually use it.
An auto_ptr can only hold a single type (no array new[] initialization is supported). It changes ownership when you pass it into functions or try and duplicate it (it's not a reference counting smart pointer).
What is a realistic usage scenario for this class give its limitations? It seems like most of the textbook examples of its use are reaching because there isn't even a reason to be using a pointer over a stack variable in most of the cases...
Anyway, I'll stop my rant - but if you can provide a short example/description or a link to a good usage scenario for this I'd be grateful. I just want to know where I should use it in practice in case I come across the situation - I like to practice what I learn so I remember it.
I'll give you a short example for a good usage. Consider this:
auto_ptr<SomeResource> some_function() {
auto_ptr<SomeResource> my_ptr = get_the_resource();
function_that_throws_an_exception();
return my_ptr;
}
The function that raises an exception would normally cause your pointer to be lost, and the object pointed to would not be deleted. With the auto_ptr this can't happen, since it is destroyed when it leaves the frame it was created, if it hasn't been assigned (for example with return).
auto_ptr has been deprecated in the now finalized C++11 standard. Some of the replacements are already available through TR1 or the Boost libraries. Examples are shared_ptr and unique_ptr (scoped_ptr in boost).
My question revolves around whether or not I must expose my use of the boost::shared_ptr from my interface and whether or not I should expose raw pointers or references from my interface.
Consider the case of a Person who has an Employeer. Employeer internally maintains all of its employees in a vector< shared_ptr< Person > >. Because of this, do best practices dictate that any interface involving Person should be a shared_ptr wrapped person?
For example, are all or only some of these ok:
Person Employeer::getPresidentCopy();
Person& Employeer::getPresidentRef();
Person* Employeer::getPresidentRawPtr();
shared_ptr<Person> Employeer::getPresidentSharedPtr();
Or for example:
void Employeer::hireByCopy(Person p);
void Employeer::hireByRef(Person& p);
void Employeer::hireByRawPtr(Person* p);
void Employeer::hireBySharedPtr(shared_ptr<Person> p);
If I later want to change the implementation to use johns_very_own_shared_ptr instead of the boost variety, am I trapped in the old implementation?
On the other hand, if I expose raw pointers or references from the interface, do I risk someone deleting the memory out from under the shared_ptr? Or do I risk the shared_ptr being deleted and making my reference invalid?
See my new question for an example involving this.
For example, are all or only some of these ok:
It depends on what you're trying to accomplish. Why does the vector hold shared_ptrs instead of just directly storing Person s by value? (And have you considered boost::ptr_vector?)
You should also consider that maybe what you really ought to hand out is a weak_ptr.
If I later want to change the implementation to use johns_very_own_shared_ptr instead of the boost variety, am I trapped in the old implementation?
Pretty much, but it's not impossible to fix. (I suspect that in C++0x, liberal use of the auto keyword will make this easier to deal with, since you won't have to modify the calling code as much, even if it didn't use typedef s.) But then, why would you ever want to do that?
On the other hand, if I expose raw pointers or references from the interface, do I risk someone deleting the memory out from under the shared_ptr?
Yes, but that's not your problem. People can extract a raw pointer from a shared_ptr and delete it, too. But if you want to avoid making things needlessly unsafe, don't return raw pointers here. References are much better because nobody ever figures they're supposed to delete &reference_received_from_api;. (I hope so, anyway ^^;;;; )
I would introduce a typedef and insulate myself against changes. Something like this:
typedef std::shared_ptr<Person> PersonPtr;
PersonPtr Employeer::getPresident() const;
I place typedefs like this one in a (just one) header together with forward declarations. This makes it easy to change if I would ever want to.
You don't have to hand out shared_ptr, but if you hand out raw pointers you run the risk of some raw pointer persisting after the object has been destroyed.
With fatal consequences.
So, handing out references generally OK (if client code takes address then that's no more your fault than if client code takes address of *shared_ptr), but raw pointers, think first.
Cheers & hth.,
I shouldn't give user raw pointers, when you use shared_ptrs. User could delete it, what will cause double deletion.
To hide usage of boost:shared_ptr you can use typedef to hide actual type, and use this new type instead.
typedef boost::shared_ptr<Person> Person_sptr;
The only reason to hand out a shared_ptr here is if the lifetime of the returned object reference is not tied directly to the lifetime of its residence in the vector.
If you want somebody to be able to access the Person after they stop being an Employee, then shared_ptr would be appropriate. Say if you are moving the Person to the vector for a different Employer.
I work on a moderately sized project that links in several libraries. Some of those libraries have their own memory management subsystems (APR, MFC) and really annoy me. Whether their view of the world is good or bad, it's entirely different from everybody else's and requires a little more code than they otherwise would.
Additionally, those libraries make swapping out malloc or new with jemalloc or the Boehm-Demers-Weiser garbage collector much harder (on Windows it's already hard enough).
I use shared pointers a lot in my own code, but I prefer not to tell others how to manage their memory. Instead, hand out objects whenever possible (letting the library user decide when and how to allocate the memory), and when it's not possible do one of:
hand out raw pointers (plus either a promise that the pointers can be deleted or a Destroy() function to call to deallocate the objects)
accept a function or STL allocator-like argument so you can hook into whatever the user's using for memory management (feel free to default to new and std::allocator)
have your library users hand you allocated memory buffers (like std::vectors)
Using this kind of library doesn't have to be nasty:
// situation (1) from above
std::shared_ptr<Foo> foo(Library_factory::get_Foo(), Library_factory::deallocate);
// situation (2) above (declaration on next line is in a header file)
template<typename allocator=std::allocator<Foo> > Foo* library_function_call();
boost::shared_ptr<Foo> foo = library_function_call();
// situation (3) above, need to fill a buffer of ten objects
std::vector<Foo> foo_buffer(10);
fill_buffer(&foo_buffer[0], foo_buffer.size());
I've been evaluating various smart pointer implementations (wow, there are a LOT out there) and it seems to me that most of them can be categorized into two broad classifications:
1) This category uses inheritance on the objects referenced so that they have reference counts and usually up() and down() (or their equivalents) implemented. IE, to use the smart pointer, the objects you're pointing at must inherit from some class the ref implementation provides.
2) This category uses a secondary object to hold the reference counts. For example, instead of pointing the smart pointer right at an object, it actually points at this meta data object... Who has a reference count and up() and down() implementations (and who usually provides a mechanism for the pointer to get at the actual object being pointed to, so that the smart pointer can properly implement operator ->()).
Now, 1 has the downside that it forces all of the objects you'd like to reference count to inherit from a common ancestor, and this means that you cannot use this to reference count objects that you don't have control over the source code to.
2 has the problem that since the count is stored in another object, if you ever have a situation that a pointer to an existing reference counted object is being converted into a reference, you probably have a bug (I.E., since the count is not in the actual object, there is no way for the new reference to get the count... ref to ref copy construction or assignment is fine, because they can share the count object, but if you ever have to convert from a pointer, you're totally hosed)...
Now, as I understand it, boost::shared_pointer uses mechanism 2, or something like it... That said, I can't quite make up my mind which is worse! I have only ever used mechanism 1, in production code... Does anyone have experience with both styles? Or perhaps there is another way thats better than both of these?
"What is the best way to implement smart pointers in C++"
Don't! Use an existing, well tested smart pointer, such as boost::shared_ptr or std::tr1::shared_ptr (std::unique_ptr and std::shared_ptr with C++ 11)
If you have to, then remember to:
use safe-bool idiom
provide an operator->
provide the strong exception guarantee
document the exception requirements your class makes on the deleter
use copy-modify-swap where possible to implement the strong exception guarantee
document whether you handle multithreading correctly
write extensive unit tests
implement conversion-to-base in such a way that it will delete on the derived pointer type (policied smart pointers / dynamic deleter smart pointers)
support getting access to raw pointer
consider cost/benifit of providing weak pointers to break cycles
provide appropriate casting operators for your smart pointers
make your constructor templated to handle constructing base pointer from derived.
And don't forget anything I may have forgotten in the above incomplete list.
Just to supply a different view to the ubiquitous Boost answer (even though it is the right answer for many uses), take a look at Loki's implementation of smart pointers. For a discourse on the design philosophy, the original creator of Loki wrote the book Modern C++ Design.
I've been using boost::shared_ptr for several years now and while you are right about the downside (no assignment via pointer possible), I think it was definitely worth it because of the huge amount of pointer-related bugs it saved me from.
In my homebrew game engine I've replaced normal pointers with shared_ptr as much as possible. The performance hit this causes is actually not so bad if you are calling most functions by reference so that the compiler does not have to create too many temporary shared_ptr instances.
Boost also has an intrusive pointer (like solution 1), that doesn't require inheriting from anything. It does require changing the pointer to class to store the reference count and provide appropriate member functions. I've used this in cases where memory efficiency was important, and didn't want the overhead of another object for each shared pointer used.
Example:
class Event {
public:
typedef boost::intrusive_ptr<Event> Ptr;
void addRef();
unsigned release();
\\ ...
private:
unsigned fRefCount;
};
inline void Event::addRef()
{
fRefCount++;
}
inline unsigned Event::release(){
fRefCount--;
return fRefCount;
}
inline void intrusive_ptr_add_ref(Event* e)
{
e->addRef();
}
inline void intrusive_ptr_release(Event* e)
{
if (e->release() == 0)
delete e;
}
The Ptr typedef is used so that I can easily switcth between boost::shared_ptr<> and boost::intrusive_ptr<> without changing any client code
If you stick with the ones that are in the standard library you will be fine.
Though there are a few other types than the ones you specified.
Shared: Where the ownership is shared between multiple objects
Owned: Where one object owns the object but transfer is allowed.
Unmovable: Where one object owns the object and it can not be transferred.
The standard library has:
std::auto_ptr
Boost has a couple more than have been adapted by tr1 (next version of the standard)
std::tr1::shared_ptr
std::tr1::weak_ptr
And those still in boost (which in relatively is a must have anyway) that hopefully make it into tr2.
boost::scoped_ptr
boost::scoped_array
boost::shared_array
boost::intrusive_ptr
See:
Smart Pointers: Or who owns you baby?
It seems to me this question is kind of like asking "Which is the best sort algorithm?" There is no one answer, it depends on your circumstances.
For my own purposes, I'm using your type 1. I don't have access to the TR1 library. I do have complete control over all the classes I need to have shared pointers to. The additional memory and time efficiency of type 1 might be pretty slight, but memory usage and speed are big issues for my code, so type 1 was a slam dunk.
On the other hand, for anyone who can use TR1, I'd think the type 2 std::tr1::shared_ptr class would be a sensible default choice, to be used whenever there isn't some pressing reason not to use it.
The problem with 2 can be worked around. Boost offers boost::shared_from_this for this same reason. In practice, it's not a big problem.
But the reason they went with your option #2 is that it can be used in all cases. Relying on inheritance isn't always an option, and then you're left with a smart pointer you can't use for half your code.
I'd have to say #2 is best, simply because it can be used in any circumstances.
Our project uses smart pointers extensively. In the beginning there was uncertainty about which pointer to use, and so one of the main authors chose an intrusive pointer in his module and the other a non-intrusive version.
In general, the differences between the two pointer types were not significant. The only exception being that early versions of our non-intrusive pointer implicitly converted from a raw pointer and this can easily lead to memory problems if the pointers are used incorrectly:
void doSomething (NIPtr<int> const &);
void foo () {
NIPtr<int> i = new int;
int & j = *i;
doSomething (&j); // Ooops - owned by two pointers! :(
}
A while ago, some refactoring resulted in some parts of the code being merged, and so a choice had to be made about which pointer type to use. The non-intrusive pointer now had the converting constructor declared as explicit and so it was decided to go with the intrusive pointer to save on the amount of code change that was required.
To our great surprise one thing we did notice was that we had an immediate performance improvement by using the intrusive pointer. We did not put much research into this, and just assumed that the difference was the cost of maintaining the count object. It is possible that other implementations of non-intrusive shared pointer have solved this problem by now.
What you are talking about are intrusive and non-intrusive smart pointers. Boost has both. boost::intrusive_ptr calls a function to decrease and increase the reference count of your object, everytime it needs to change the reference count. It's not calling member functions, but free functions. So it allows managing objects without the need to change the definition of their types. And as you say, boost::shared_ptr is non-intrusive, your category 2.
I have an answer explaining intrusive_ptr: Making shared_ptr not use delete. In short, you use it if you have an object that has already reference counting, or need (as you explain) an object that is already referenced to be owned by an intrusive_ptr.