Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

When in particular smart pointers are very good to use and why use a smart pointer anyway if pointers in C++ are discouraged to use? As an example code 'cause I cannot express it in words:

class Object {  }

smart_pointer < Object > pInstance;
//wherein I can use the very simple way
Object instance;

Please don't discourage a noob people like me to ask questions here in stackoverflow by your downvotes :) peace

share|improve this question
8  
"pointers in C++ are discouraged to use". Well, how would polymorphism work if you can't use pointers ? Pointers are needed, smart pointers make pointer's use safer/easier/better. –  JBL Jun 12 '13 at 9:52
    
Use pointers only if you have to. And when you do, try to use smart pointers instead of raw ones. –  Morwenn Jun 12 '13 at 9:54
    
When attaching a code sample, attach a valid code at least. –  LihO Jun 12 '13 at 9:54
2  
Unfortunately statically allocated objects, while being the preferred and default way, are not sufficient in all cases, like situations with hard to define object lifetime (not directly bound to the lifetime of a function call or another object), or when the need for dynamic polymorphism arises. And in those cases dynamic memory allocation is often the best way to solve it, and made much more easy and safe through smart pointers. –  Christian Rau Jun 12 '13 at 10:00
1  
Downvotes are the sign that something might be wrong with your question; they are by no means personal or meant to discourage you. You might want to review FAQ and About pages, to ensure your question is OK. –  Bartek Banachewicz Jun 12 '13 at 11:42

2 Answers 2

Smart pointers are good when you need to maintain ownership of an object. Using them will ensure proper destruction. When pointer is treated as a reference, using smart pointer can sometimes be worse (for example, in terms of performance).

Pointers are an essential part of C++, but using them got much easier as smart ones in C++11 with move semantics introduced (which essentially made unique_ptr possible). That's why in modern code you should always use std::unique_ptr or std::shared_ptr if available.


Edit: You asked for an example, where a pointer could be beneficial to use. The most common problem that I can think of is an optional component of some system. This component will use a lot of memory, so you don't want to always allocate it, neither you control its allocations (so it can't be in "empty" state itself, i.e. is not nullable). Boost.Optional and C++14-ish std::optional allocate memory of the POD-ish size of T, so they won't do. Using a pointer you can optionally allocate that memory:

class Outer { 
    std::unique_ptr<BigInner> optionalComponent;
public:
    void initializeOptionalComponent() { 
        optionalComponent = new BigInner();
    }
    void useOptionalComponent() {
        if (!optionalComponent)
            // handle the error
        // operate
    } 
};

That will solve the problem, but will introduce the obvious, another problem: optionalComponent can be null, which requires all functions using it to check for valid state at all times. Had it been a plain by-value member, it would (or at least should) be always in valid state. As such, if you don't need a pointer, don't use it at all, use vector<MyClass> and plain members.

Anyway, using smart pointer in this case allows you to keep the Rule of Zero; you don't have to write destructor, copy constructor or assignment operator, and the class will behave safely.

share|improve this answer
    
Can you give me an example wherein I should wrap the object with smart pointer or not. As in my example above. –  user2477739 Jun 12 '13 at 10:05

Quick answer : smart pointers are useful for (notably)

  • Enforcing RAII
  • Managing pointers ownership

Enforcing RAII

One problem that comes with pointers and cause (in many way, some obvious, some twisted) crashes in your program is that you are responsible for the memory underneath them. That means that when you allocate memory dynamically (through new), you are responsible for this memory, and must not forget to call delete. That means it will happen, and worse, there are case where even if you didn't forget, the delete statement will never be reached. Consider this code :

void function(){
    MyClass* var = new MyClass;

    //Do something

    delete var;
}

Now, if this function throw an exception before the delete statement is reached, the pointer will not be deleted... Memory leak !

RAII is a way to avoid this :

void function(){
    std::shared_ptr<MyClass> var(new MyClass);

    //Do something

    //No need to delete anything
}

The pointer is held by an object, and deleted in its destructor. The difference with the previous code is that, if the function throw an exception, the destructor of the shared pointer will be called and the pointers will thus be deleted, avoiding a memory leak.

RAII takes advantages of the fact that when a local variable goes out of scope, its dtor is called.

Managing pointers ownership

Note which smart pointer I used in the previous example. The std::shared_ptr is a smart pointer that is useful when you pass pointers around. If many part of your code need a pointer to the same object, it can be tricky to decide where it should be deleted. You might want to delete the pointer somewhere, but what if another part of your code is using it ? It results in an access to a deleted pointer, which is not desirable at all ! std::shared_ptr helps prevent this. When you pass a shared_ptr around, it keeps track of how many part of the code have a reference to it. When there isn't any reference to the pointer anymore, this pointer deletes the memory. In other terms when nobody uses the pointer anymore, it is safely deleted.

There are other kind of smart pointers that address other issue, like std::unique_ptr which provide a pointer that is the only owner of the pointer underneath it.

Note - Small explanation on polymorphism

You need pointers to use polymorphism. If you have an abstract class MyAbstract (that means, it have at least one virtual, say doVirtual()), it cannot be instantiated. The following code :

MyAbstract var;

won't compile, you'll get something along the line of Can't instantiate abstract class from your compiler.

But this is legal (with both ImplA and ImplB inheriting publicly from MyAbstract:

MyAbstract* varA = new ImplA;
MyAbstract* varB = new ImplB;

varA->doVirtual(); //Will call ImplA implementation
varB->doVirtual(); //Will call ImplB implementation

delete varA;
delete varB;
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.