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I'm coming from a Java background and have started working with objects in C++. But one thing that occurred to me is that people often use pointers to objects rather than the objects themselves, for example this declaration:

Object *myObject = new Object;

rather than:

Object myObject;

Or instead of using a function, let's say testFunc(), like this:


we have to write:


But I can't figure out why should we do it this way. I would assume it has to do with efficiency and speed since we get direct access to the memory address. Am I right?

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Kudos to you for questioning this practice rather than just following it. Most of the time, pointers are over-used. –  Luchian Grigore Mar 3 '14 at 11:56
If you don't see a reason to use pointers, don't. Prefer objects. Prefer objects before unique_ptr before shared_ptr before raw pointers. –  stefan Mar 3 '14 at 12:00
note: in java, everything(except basic types) is a pointer. so you rather should ask the opposite: why do I need simple objects? –  Karoly Horvath Mar 3 '14 at 12:01
Note that, in Java, pointers are hidden by syntax. In C++, the difference between a pointer and a non-pointer is made explicit in code. Java uses pointers everywhere. –  Daniel Martín Mar 3 '14 at 12:04
Close as too broad? Seriously? Please people, note that this Java++ way of programming is very common and one of the most important problems on the C++ community. It should be treated seriously. –  Manu343726 Mar 3 '14 at 22:53

16 Answers 16

up vote 836 down vote accepted

It's very unfortunate that you see dynamic allocation so often. That just shows how many bad C++ programmers there are.

In a sense, you have two questions bundled up into one. The first is when should we use dynamic allocation (using new)? The second is when should we use pointers?

The important take-home message is that you should always use the appropriate tool for the job. In almost all situations, there is something more appropriate and safer than performing manual dynamic allocation and/or using raw pointers.

Dynamic allocation

In your question, you've demonstrated two ways of creating an object. The main difference is the storage duration of the object. When doing Object myObject; within a block, the object is created with automatic storage duration, which means it will be destroyed automatically when it goes out of scope. When you do new Object(), the object has dynamic storage duration, which means it stays alive until you explicitly delete it. You should only use dynamic storage duration when you need it. That is, you should always prefer creating objects with automatic storage duration when you can.

The main two situations in which you might require dynamic allocation:

  1. You need the object to outlive the current scope - that specific object at that specific memory location, not a copy of it. If you're okay with copying/moving the object (most of the time you should be), you should prefer an automatic object.
  2. You need to allocate a lot of memory, which may easily fill up the stack. It would be nice if we didn't have to concern ourselves with this (most of the time you shouldn't have to), as it's really outside the purview of C++, but unfortunately we have to deal with the reality of the systems we're developing for.

When you do absolutely require dynamic allocation, you should encapsulate it in a smart pointer or some other type that performs RAII (like the standard containers). Smart pointers provide ownership semantics of dynamically allocated objects. Take a look at std::unique_ptr and std::shared_ptr, for example. If you use them appropriately, you can almost entirely avoid performing your own memory management (see the Rule of Zero).


However, there are other more general uses for raw pointers beyond dynamic allocation, but most have alternatives that you should prefer. As before, always prefer the alternatives unless you really need pointers.

  1. You need reference semantics. Sometimes you want to pass an object using a pointer (regardless of how it was allocated) because you want the function to which you're passing it to have access that that specific object (not a copy of it). However, in most situations, you should prefer reference types to pointers, because this is specifically what they're designed for. Note this is not necessarily about extending the lifetime of the object beyond the current scope, as in situation 1 above. As before, if you're okay with passing a copy of the object, you don't need reference semantics.

  2. You need polymorphism. You can only call functions polymorphically (that is, according to the dynamic type of an object) through a pointer or reference to the object. If that's the behaviour you need, then you need to use pointers or references. Again, references should be preferred.

  3. You want to represent that an object is optional by allowing a nullptr to be passed when the object is being omitted. If it's an argument, you should prefer to use default arguments or function overloads. Otherwise, you should prefer use a type that encapsulates this behaviour, such as boost::optional (or perhaps soon, std::optional - Edit std::optional is voted out of the current C++14 draft n3797).

  4. You want to decouple compilation units to improve compilation time. The useful property of a pointer is that you only require a forward declaration of the pointed-to type (to actually use the object, you'll need a definition). This allows you to decouple parts of your compilation process, which may significantly improve compilation time. See the Pimpl idiom.

  5. You need to interface with a C library or a C-style library. At this point, you're forced to use raw pointers. The best thing you can do is make sure you only let your raw pointers loose at the last possible moment. You can get a raw pointer from a smart pointer, for example, by using its get member function. If a library performs some allocation for you which it expects you to deallocate via a handle, you can often wrap the handle up in a smart pointer with a custom deleter that will deallocate the object appropriately.

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"You need the object to outlive the current scope." -- An additional note about this: there are cases where it seems like you need the object to outlive the current scope, but you really don't. If you put your object inside a vector, for example, the object will be copied (or moved) into the vector, and the original object is safe to destroy when its scope ends. –  hvd Mar 3 '14 at 12:03
Remember that s/copy/move/ in many places now. Returning an object definitely does not imply a move. You should also note that accessing an object through a pointer is orthogonal to how it was created. –  Puppy Mar 3 '14 at 12:10
I miss an explicit reference to RAII on this answer. C++ is all (almost all) about resource management, and RAII is the way to do it on C++ (And the main problem which raw pointers generate: Breaking RAII) –  Manu343726 Mar 3 '14 at 23:01
Smart pointers existed before C++11, e.g. boost::shared_ptr and boost::scoped_ptr. Other projects have their own equivalent. You can't get move semantics, and std::auto_ptr's assign is flawed, so C++11 improves things, but the advice is still good. (And a sad nitpick, it's not enough to have access to a C++11 compiler, it's necessary that all the compilers you might possibly want your code to work with support C++11. Yes, Oracle Solaris Studio, I'm looking at you.) –  armb Mar 5 '14 at 15:29
@MDMoore313 You can write Object myObject(param1, etc...) –  user000001 Mar 9 '14 at 14:41

There are many use cases for pointers.

Polymorphic behavior. For polymorphic types, pointers (or references) are used to avoid slicing:

class Base { ... };
class Derived : public Base { ... };

void fun(Base b) { ... }
void gun(Base* b) { ... }
void hun(Base& b) { ... }

Derived d;
fun(d);    // oops, all Derived parts silently "sliced" off
gun(&d);   // OK, a Derived object IS-A Base object
hun(d);    // also OK, reference also doesn't slice

Reference semantics and avoiding copying. For non-polymorphic types, a pointer (or a reference) will avoid copying a potentially expensive object

Base b;
fun(b);  // copies b, potentially expensive 
gun(&b); // takes a pointer to b, no copying
hun(b);  // regular syntax, behaves as a pointer

Note that C++11 has move semantics that can avoid many copies of expensive objects into function argument and as return values. But using a pointer will definitely avoid those and will allow multiple pointers on the same object (whereas an object can only be moved from once).

Resource acquisition. Creating a pointer to a resource using the new operator is an anti-pattern in modern C++. Use a special resource class (one of the Standard containers) or a smart pointer (std::unique_ptr<> or std::shared_ptr<>). Consider:

    auto b = new Base;
    ...       // oops, if an exception is thrown, destructor not called!
    delete b;


    auto b = std::make_unique<Base>();
    ...       // OK, now exception safe

A raw pointer should only be used as a "view" and not in any way involved in ownership, be it through direct creation or implicitly through return values. See also this Q&A from the C++ FAQ.

More fine-grained life-time control Every time a shared pointer is being copied (e.g. as a function argument) the resource it points to is being kept alive. Regular objects (not created by new, either directly by you or inside a resource class) are destroyed when going out of scope.

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"Creating a pointer to a resource using the new operator is an anti-pattern" I think you could even enhance that to having a raw pointer own something is an anti-pattern. Not only the creation, but passing raw pointers as arguments or return values implying ownership transfer IMHO is deprecated since unique_ptr/move semantics –  dyp Mar 3 '14 at 12:29
@dyp tnx, updated and reference to the C++ FAQ Q&A on this topic. –  TemplateRex Mar 3 '14 at 12:33
Using smart pointers everywhere is an anti-pattern. There are a few special cases where it is applicable, but most of the time, the same reason which argue for dynamic allocation (arbitrary lifetime) argue against any of the usual smart pointers as well. –  James Kanze Mar 3 '14 at 13:26
@JamesKanze I didn't mean to imply that smart pointers should be used everywhere, just for ownership, and also that raw pointers should not be used for ownership, but only for views. –  TemplateRex Mar 3 '14 at 13:28
@TemplateRex That seems slightly silly given that hun(b) also requires knowledge of the signature unless you're fine with not knowing that you supplied the wrong type until compilation. While the reference issue usually won't get caught at compile time and would take more effort to debug, if you're checking the signature to make sure the arguments are right you'll also be able to see if any of the arguments are references so the reference bit becomes something of a non-problem (especially when using IDEs or text editors that show the signature of a selected functions). Also, const&. –  JAB Mar 3 '14 at 16:04

Another good reason to use pointers would be for forward declarations. In a large enough project they can really speed up compile time.

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this is really adding to the mix of useful info, so glad you made it an answer! –  TemplateRex Mar 4 '14 at 21:39
References work for this too. –  Zan Lynx Mar 5 '14 at 22:18
std::shared_ptr<T> also works with forward declarations of T. (std::unique_ptr<T> doesn't) –  berkus Mar 14 '14 at 10:23
@berkus: std::unique_ptr<T> does work with forward declarations of T. You just need to make sure that when the destructor of the std::unique_ptr<T> is called, T is a complete type. This typically means your class that contains the std::unique_ptr<T> declares its destructor in the header file and implements it in the cpp file (even if the implementation is empty). –  David Stone Nov 27 '14 at 16:25
@DavidStone Thanks, it worked! –  berkus Nov 27 '14 at 22:51

There are many excellent answers to this question, but I feel a part of the "soul" of your question is not answered - namely what the different syntaxes mean across Java and C++.

Let's examine these two statements:


Object object1 = new Object(); //A new object is allocated by Java
Object object2 = new Object(); //Another new object is allocated by Java

object1 = object2; 
//object1 now points to the object originally allocated for object2
//The object originally allocated for object1 is now "dead", and will be reclaimed 
//by the Garbage Collector.
//If either object1 or object2 is changed, the change will be reflected to the other

The closest equivalent to this, is:


Object * object1 = new Object(); //A new object is allocated on the heap
Object * object2 = new Object(); //Another new object is allocated on the heap
delete object1;
//Since C++ does not have a garbage collector, if we don't do that we get a "memory leak",
//i.e. a piece of claimed memory that the app cannot use and we cannot reclaim it.

object1 = object2; //Same as Java, object1 points to object2.

Let's see the alternative C++ way:

Object object1; //A new object is allocated on the STACK
Object object2; //Another new object is allocated on the STACK
object1 = object2;//!!!! This is different! The CONTENTS of object2 are COPIED onto object1,
//using the copy assignment operator.
//But, the two objects are still different. Change one, the other remains unchanged.
//Also, the objects get automatically destroyed once the function returns...

The best way to think of it is that -- more or less -- Java (implicitly) handles pointers to objects, while C++ may handle either pointers to objects, or the objects themselves. There are exceptions to this -- for example, if you declare Java "primitive" types, they are actual values that are copied, and not pointers. So,


int object1; //An integer is allocated on the stack.
int object2; //Another integer is allocated on the stack.
object1 = object2; //The value of object2 is copied to object1.

That said, using pointers is NOT necessarily the correct way to handle things. Neither is it necessarily wrong. Other answers have covered that satisfactorily though. The idea is though that in C++ you have much more control on the lifetime of the objects, and on where they will live.

Take home point -- the Object * object = new Object() construct is actually what is closest to typical Java (or C# for that matter) semantics.

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Object2 is now "dead": I think you mean myObject1 or more precisely the object pointed to by myObject1. –  Clément Mar 10 '14 at 8:51
Indeed! Rephrased a bit. –  Gerasimos R Dec 14 '14 at 12:38


Java is nothing like C++, contrary to hype. The Java hype machine would like you to believe that because Java has C++ like syntax, that the languages are similar. Nothing can be further from the truth. This misinformation is part of the reason why Java programmers go to C++ and use Java-like syntax without understanding the implications of their code.

Onwards we go

But I can't figure out why should we do it this way. I would assume it has to do with efficiency and speed since we get direct access to the memory address. Am I right?

To the contrary, actually. The heap is much slower than the stack, because the stack is very simple compared to the heap. Automatic storage variables (aka stack variables) have their destructors called once they go out of scope. For example:

    std::string s;
// s is destroyed here

On the other hand, if you use a pointer dynamically allocated, its destructor must be called manually. delete calls this destructor for you.

    std::string* s = new std::string;
delete s; // destructor called

This has nothing to do with the new syntax prevalent in C# and Java. They are used for completely different purposes.

Benefits of dynamic allocation

1. You don't have to know the size of the array in advance

One of the first problems many C++ programmers run into is that when they are accepting arbitrary input from users, you can only allocate a fixed size for a stack variable. You cannot change the size of arrays either. For example:

char buffer[100];
std::cin >> buffer;
// bad input = buffer overflow

Of course if you used an std::string instead, std::string internally resizes itself so that shouldn't be a problem. But essentially the solution to this problem is dynamic allocation. You can allocate dynamic memory based on input of the user, for example:

int * pointer;
std::cout << "How many items do you need?";
std::cin >> n;
pointer = new int[n];

Side note: One mistake many beginners make is the usage of variable length arrays. This is a GNU extension and also one in Clang because they mirror many of GCC's extensions. So the following int arr[n] should not be relied on.

Because the heap is much bigger than the stack, one can arbitrary allocate/reallocate as much memory as he/she needs, whereas the stack has a limitation.

2. Arrays are not pointers

How is this a benefit you ask? The answer will become clear once you understand the confusion/myth behind arrays and pointers. It is commonly assumed that they are the same, but they are not. This myth comes from the fact that pointers can be subscripted just like arrays and because arrays decay to pointers at the top level in a function declaration. However, once an array decays to a pointer, the pointer loses its sizeof information. So sizeof(pointer) will give the size of the pointer in bytes, which is usually 8 bytes on a 64-bit system.

You cannot assign to arrays, only initialize them. For example:

int arr[5] = {1, 2, 3, 4, 5}; // initialization 
int arr[] = {1, 2, 3, 4, 5}; // The standard dictates that the size of the array
                             // be given by the amount of members in the initializer  
arr = { 1, 2, 3, 4, 5 }; // ERROR

On the other hand, you can do whatever you want with pointers. Unfortunately because the distinction between pointers and arrays are hand-waved in Java and C#, beginners don't understand the difference.

3. Polymorphism

Java and C# have facilities that allow you to treat objects as another, for example using the as keyword. So if somebody wanted to treat an Entity object as a Player object, one could do Player player = Entity as Player; This is very useful if you intend to call functions on a homogeneous container that should only apply to a specific type. The functionality can be achieved in a similar fashion below:

std::vector<Base*> vector;
for (auto& e : vector)
     auto test = dynamic_cast<Triangle*>(e); // I only care about triangles
     if (!test) // not a triangle

So say if only Triangles had a Rotate function, it would be a compiler error if you tried to call it on all objects of the class. Using dynamic_cast, you can simulate the as keyword. To be clear, if a cast fails, it returns an invalid pointer. So !test is essentially a shorthand for checking if test is NULL or an invalid pointer, which means the cast failed.

Benefits of automatic variables

After seeing all the great things dynamic allocation can do, you're probably wondering why wouldn't anyone NOT use dynamic allocation all the time? I already told you one reason, the heap is slow. And if you don't need all that memory, you shouldn't abuse it. So here's some disadvantages in no particular order:

  • It is error prone. Manual memory allocation is dangerous and you are prone to leaks. If you are not proficient at using the debugger or valgrind (a memory leak tool), you may pull your hair out of your head. Luckily RAII idioms and smart pointers alleviate this a bit, but you must be familiar with practices such as The Rule Of Three and The Rule Of Five. It is a lot of information to take in, and beginners who either don't know or don't care will fall into this trap.

  • It is not necessary. Unlike Java and C# where it is idiomatic to use the new keyword everywhere, in C++, you should only use it if you need to. The common phrase goes, everything looks like a nail if you have a hammer. Whereas beginners who start with C++ are scared of pointers and learn to use stack variables by habit, Java and C# programmers start by using pointers without understanding it! That is literally stepping off on the wrong foot. You must abandon everything you know because syntax is one thing, learning the language is another.

1. (N)RVO - Aka, (Named) Return Value Optimization

One optimization many compilers make are things called elision and return value optimization. These things can obviate unnecessary copys which is useful for objects that are very large, such as a vector containing many elements. Normally the common practice is to use pointers to transfer ownership rather than copying the large objects to move them around. This has lead to the inception of move semantics and smart pointers.

If you are using pointers, (N)RVO does NOT occur. It is more beneficial and less error-prone to take advantage of (N)RVO rather than returning or passing pointers if you are worried about optimization. Error leaks can happen if the caller of a function is responsible for deleteing a dynamically allocated object and such. It can be difficult to track the ownership of an object if pointers are being passed around like a hot potato. Just use stack variables because it is simpler and better.

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"So !test is essentially a shorthand for checking if test is NULL or an invalid pointer, which means the cast failed." I think this sentence must be rewritten for clarity. –  berkus Mar 14 '14 at 10:34
"The Java hype machine would like you to believe" -- maybe in 1997, but this is now anachronistic, there's no longer motivation to compare Java to C++ in 2014. –  Matt R Mar 14 '14 at 13:52
Old question, but in the code segment { std::string* s = new std::string; } delete s; // destructor called ....surely this delete won't work because the compiler won't know what s is anymore? –  Johnny Lyco Jun 29 '14 at 22:55
"...the distinction between pointers and arrays are hand-waved in Java..." Not at all. Setting aside that Java doesn't have pointers (it has nullable references), arrays are a type like any other. You can't "handwave" the reference by discarding array syntax and pretending it is a reference to its first element. int[] nums = { 0 }; int zero = nums; won't compile. –  Justin Nov 5 '14 at 21:41
@Justin What are pointers if not nullable references? –  ʎǝɹɟɟɟǝſ May 20 at 13:35

But I can't figure out why should we use it like this?

I will compare how it works inside function body, if you use:

Object myObject;

inside function, your myObject will get destroyed once this function returns. So this is usefull if you dont need your object outside your function. This object will be put on current thread stack.

If you write inside function body:

 Object *myObject = new Object;

then Object class instance pointed by myObject will not get destroyed once function ends, and allocation is on heap.

Now if you are java programmer, then the second example is closer to how object allocation works under java. This line: Object *myObject = new Object; is equivalent to java: Object myObject = new Object();. The difference is that under java myObject will get garbage collected, while under c++ it will not get freed, you must somewhere explicitly call `delete myObject;' otherwise you will introduce memory leaks.

Since c++11 you can use safe ways of dynamic allocations: new Object, by storing values in shared_ptr/unique_ptr.

std::shared_ptr<std::string> safe_str = make_shared<std::string>("make_shared");

// since c++14
std::unique_ptr<std::string> safe_str = make_unique<std::string>("make_shared"); 

also, objects are very often stored in containers, like map-s or vector-s, they will automatically manage lifetime of your objects.

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then myObject will not get destroyed once function ends It absolutely will. –  Lightness Races in Orbit Mar 3 '14 at 12:49
In the pointer case, myObject will still be destroyed, just as any other local variable will. The difference is that its value is a pointer to an object, not the object itself, and a dumb pointer's destruction doesn't affect its pointee. So the object will survive said destruction. –  cHao Mar 3 '14 at 15:45
Fixed that, local variables (that includes pointer) of course will be freed - they are on stack. –  marcinj Mar 3 '14 at 16:06

In C++, objects allocated on the stack (using Object object; statement within a block) will only live within the scope they are declared in. When the block of code finishes execution, the object declared are destroyed. Whereas if you allocate memory on heap, using Object* obj = new Object(), they continue to live in heap until you call delete obj.

I would create an object on heap when I like to use the object not only in the block of code which declared/allocated it.

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Object obj is not always on the stack - for example globals or member variables. –  tenfour Mar 3 '14 at 12:03
@tenfour Yes. I know that :) –  Karthik Kalyanasundaram Mar 3 '14 at 12:05
Then you knowingly wrote false information! –  Lightness Races in Orbit Mar 3 '14 at 12:49
@LightnessRacesinOrbit I mentioned only about the objects allocated in a block, not about global and member variables. Thing is it was not clear, now corrected it - added "within a block" in the answer. Hope its not false information now :) –  Karthik Kalyanasundaram Mar 4 '14 at 9:51

C++ gives you three ways to pass an object: by pointer, by reference, and by value. Java limits you with the latter one (the only exception is primitive types like int, boolean etc). If you want to use C++ not just like a weird toy, then you'd better get to know the difference between these three ways.

Java pretends that there is no such problem as 'who and when should destroy this?'. The answer is: The Garbage Collector, Great and Awful. Nevertheless, it can't provide 100% protection against memory leaks (yes, java can leak memory). Actually, GC gives you a false sense of safety. The bigger your SUV, the longer your way to the evacuator.

C++ leaves you face-to-face with object's lifecycle management. Well, there are means to deal with that (smart pointers family, QObject in Qt and so on), but none of them can be used in 'fire and forget' manner like GC: you should always keep in mind memory handling. Not only should you care about destroying an object, you also have to avoid destroying the same object more than once.

Not scared yet? Ok: cyclic references - handle them yourself, human. And remember: kill each object precisely once, we C++ runtimes don't like those who mess with corpses, leave dead ones alone.

So, back to your question.

When you pass your object around by value, not by pointer or by reference, you copy the object (the whole object, whether it's a couple of bytes or a huge database dump - you're smart enough to care to avoid latter, aren't you?) every time you do '='. And to access the object's members, you use '.' (dot).

When you pass your object by pointer, you copy just a few bytes (4 on 32-bit systems, 8 on 64-bit ones), namely - the address of this object. And to show this to everyone, you use this fancy '->' operator when you access the members. Or you can use the combination of '*' and '.'.

When you use references, then you get the pointer that pretends to be a value. It's a pointer, but you access the members through '.'.

And, to blow your mind one more time: when you declare several variables separated by commas, then (watch the hands):

  • Type is given to everyone
  • Value/pointer/reference modifier is individual


struct MyStruct
    int* someIntPointer, someInt; //here comes the surprise
    MyStruct *somePointer;
    MyStruct &someReference;

MyStruct s1; //we allocated an object on stack, not in heap

s1.someInt = 1; //someInt is of type 'int', not 'int*' - value/pointer modifier is individual
s1.someIntPointer = &s1.someInt;
*s1.someIntPointer = 2; //now s1.someInt has value '2'
s1.somePointer = &s1;
s1.someReference = s1; //note there is no '&' operator: reference tries to look like value
s1.somePointer->someInt = 3; //now s1.someInt has value '3'
*(s1.somePointer).someInt = 3; //same as above line
*s1.somePointer->someIntPointer = 4; //now s1.someInt has value '4'

s1.someReference.someInt = 5; //now s1.someInt has value '5'
                              //although someReference is not value, it's members are accessed through '.'

MyStruct s2 = s1; //'NO WAY' the compiler will say. Go define your '=' operator and come back.

//OK, assume we have '=' defined in MyStruct

s2.someInt = 0; //s2.someInt == 0, but s1.someInt is still 5 - it's two completely different objects, not the references to the same one
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std::auto_ptr is deprecated, please don't use it. –  Neil Mar 9 '14 at 19:53
Thanks for std::pointing this out, I've edited the answer –  Kirill Gamazkov Mar 9 '14 at 20:17
Pretty sure you can't have a reference as a member without also providing a constructor with an initialization list that includes the reference variable. (A reference has to be initialized immediately. Even the constructor body is too late to set it, IIRC.) –  cHao Jul 25 '14 at 19:32

Technically it is a memory allocation issue, however here are two more practical aspects of this. It has to do with two things: 1) Scope, when you define an object without a pointer you will no longer be able to access it after the code block it is defined in, whereas if you define a pointer with "new" then you can access it from anywhere you have a pointer to this memory until you call "delete" on the same pointer. 2) If you want to pass arguments to a function you want to pass a pointer or a reference in order to be more efficient. When you pass an Object then the object is copied, if this is an object that uses a lot of memory this might be CPU consuming (e.g. you copy a vector full of data). When you pass a pointer all you pass is one int (depending of implementation but most of them are one int).

Other than that you need to understand that "new" allocates memory on the heap that needs to be freed at some point. When you don't have to use "new" I suggest you use a regular object definition "on the stack".

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Let's say that you have class A that contain class B When you want to call some function of class B outside class A you will simply obtain a pointer to this class and you can do whatever you want and it will also change context of class B in your class A

But be careful with dynamic object

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There are many benefits of using pointers to object -

  1. Efficiency (as you already pointed out). Passing objects to functions mean creating new copies of object.
  2. Working with objects from third party libraries. If your object belongs to a third party code and the authors intend the usage of their objects through pointers only (no copy constructors etc) the only way you can pass around this object is using pointers. Passing by value may cause issues. (Deep copy / shallow copy issues).
  3. if the object owns a resource and you want that the ownership should not be sahred with other objects.
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This is has been discussed at length, but in Java everything is a pointer. It makes no distinction between stack and heap allocations (all objects are allocated on the heap), so you don't realize you're using pointers. In C++, you can mix the two, depending on your memory requirements. Performance and memory usage is more deterministic in C++ (duh).

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Well the main question is Why should I use a pointer rather than the object itself? And my answer, you should (almost) never use pointer instead of object, because C++ has references, it is safer then pointers and guarantees the same performance as pointers.

Another thing you mentioned in your question:

Object *myObject = new Object;

How does it work? It creates pointer of Object type, allocates memory to fit one object and calls default constructor, sounds good, right? But actually it isn't so good, if you dynamically allocated memory (used keyword new), you also have to free memory manually, that means in code you should have:

delete myObject;

This calls destructor and frees memory, looks easy, however in big projects may be difficult to detect if one thread freed memory or not, but for that purpose you can try shared pointers, these slightly decreases performance, but it is much easier to work with them.

And now some introduction is over and go back to question.

You can use pointers instead of objects to get better performance while transferring data between function.

Take a look, you have std::string (it is also object) and it contains really much data, for example big XML, now you need to parse it, but for that you have function void foo(...) which can be declarated in different ways:

  1. void foo(std::string xml); In this case you will copy all data from your variable to function stack, it takes some time, so your performance will be low.
  2. void foo(std::string* xml); In this case you will pass pointer to object, same speed as passing size_t variable, however this declaration has error prone, because you can pass NULL pointer or invalid pointer. Pointers usually used in C because it doesn't have references.
  3. void foo(std::string& xml); Here you pass reference, basically it is the same as passing pointer, but compiler does some stuff and you cannot pass invalid reference (actually it is possible to create situation with invalid reference, but it is tricking compiler).
  4. void foo(const std::string* xml); Here is the same as second, just pointer value cannot be changed.
  5. void foo(const std::string& xml); Here is the same as third, but object value cannot be changed.

What more I want to mention, you can use these 5 ways to pass data no matter which allocation way you have chosen (with new or regular).

Another thing to mention, when you create object in regular way, you allocate memory in stack, but while you create it with new you allocate heap. It is much faster to allocate stack, but it is kind a small for really big arrays of data, so if you need big object you should use heap, because you may get stack overflow, but usually this issue is solved using STL containers and remember std::string is also container, some guys forgot it :)

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A pointer directly references the memory location of an object. Java has nothing like this. Java has references that reference the location of object through hash tables. You cannot do anything like pointer arithmetic in Java with these references.

To answer your question, it's just your preference. I prefer using the Java-like syntax.

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Hash tables? Maybe in some JVMs but don't count on it. –  Zan Lynx Mar 5 '14 at 22:21
You can use MyClass[] to emulate pointer math –  Kirill Gamazkov Mar 9 '14 at 20:20
What about the JVM that comes with Java? Of course you can implement ANYTHING you can think of like a JVM that uses pointers directly or a method that does pointer math. That's like saying "people don't die of the common cold" and getting a response "Maybe most people don't but don't count on it!" Ha ha. –  RioRicoRick Mar 25 at 16:49

"Necessity is the mother of invention." The most of important difference that I would like to point out is the outcome of my own experience of coding. Sometimes you need to pass objects to functions . In that case if your object is of a very big class then passing it as an object will copy its state (which you might not want ..AND CAN BE BIG OVERHEAD) thus resulting in overhead of copying object .while pointer is fixed 4 byte size (assuming 32 bit).Other reasons are already mentioned above...

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you should prefer passing by reference –  bolov Mar 6 '14 at 8:20

There are many excellent answers already, but let me give you one example:

I have an simple Item class:

 class Item
      std::string name;
      int weight;
      int price;

I make a vector to hold a bunch of them.

std::vector<Item> inventory;

I create one million Item objects, and push them back onto the vector. I sort the vector by name, and then do a simple iterative binary search for a particular item name. I test the program, and it takes over 8 minutes to finish executing. Then I change my inventory vector like so:

std::vector<Item *> inventory;

...and create my million Item objects via new. The ONLY changes I make to my code are to use the pointers to Items, excepting a loop I add for memory cleanup at the end. That program runs in under 40 seconds, or better than a 10x speed increase. EDIT: The code is at http://pastebin.com/DK24SPeW With compiler optimizations it shows only a 3.4x increase on the machine I just tested it on, which is still considerable.

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Well are you comparing the pointers then or do you still compare the actual objects? I very much doubt that another level of indirection can improve performance. Please provide code! Do you properly clean up afterwards? –  stefan Feb 5 at 18:38
@stefan I compare the data (specifically, the name field) of the objects for both the sort and the search. I clean up properly, as I mentioned already in the post. the speedup is probably due to two factors: 1) std::vector push_back() copies the objects, so the pointer version only need copy a single pointer per object. This has multiple impacts on the performance, as not only is less data copied, but the vector class memory allocator gets thrashed less. –  Darren Feb 5 at 21:48
well then please show the code –  stefan Feb 5 at 21:49
2) The sort just has to exchange pointers, not entire objects (I just used the std::sort algorithm with a simple string comparison in both cases, adapted to dereference the pointers in the second case). Again, I emphasize: "The ONLY changes I make to my code are to use the pointers to Items, excepting a loop I add for memory cleanup at the end." –  Darren Feb 5 at 21:49
Here's code showing practically no difference for your example: sorting. The pointer code is 6% faster than the non-pointer code for the sort alone, but overall it's 10% slower than the non-pointer code. ideone.com/G0c7zw –  stefan Feb 5 at 22:31

protected by Charles Mar 7 '14 at 22:26

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