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So I first learned Java and now I'm trying to switch over to C++. I'm having a little difficulty getting arrays to work correctly.

Right now I am simply trying to create an array of object "Player" and populate it with on. But I get an error.

Player* players = new Player[1];
players[0] = new Player(playerWidth, playerHeight, 20, 1);

The error says: the operand "=" matches these operands. Operand types are: Player = Player *

I can't understand why this doesn't work?

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8  
First lesson: stop using new unless you really really need to. –  juanchopanza Jan 15 '13 at 19:07
3  
You don't need new to create an object in C++ and you should prefer std::array and std::vector instead of built-in arrays. –  chris Jan 15 '13 at 19:07
    
The advice about new is sound. Remember, C++ isn't garbage collected, which means when you use new, you're stuck manually freeing the memory. –  RonaldBarzell Jan 15 '13 at 19:11
1  
@sgar91: In Java it does not return an object, it creates an object and returns a reference. In C++ it creates an object and it returns a pointer. The main difference is that for all but primitive types in Java (language with reference semantics) everything is a reference, while in C++ (language with value semantics) everything is an object (including pointers) –  David Rodríguez - dribeas Jan 15 '13 at 19:19
2  
@sgar91 C++ semantics are indeed very different from Java. new however is rather similar (though related concepts differ): In Java, it returns a reference (in the Java sense), while in C++ it returns a raw pointer. And a Java reference is very much like a more restricted C++ pointer. –  delnan Jan 15 '13 at 19:19

6 Answers 6

up vote 6 down vote accepted

What the error is saying is that you are trying to assign a value of the wrong type to the variable. When the error says Player = Player * that means that the variable on the left hand side is a Player and the value on the right hand side is a Player *.

players[0] = new Player(playerWidth, playerHeight, 20, 1);

The problem is similar to if you were to do:

int x;
x = "Hello, World!";

The left and right hand types don't match, and there's no natural conversion, so you get an error.


The first problem is that you're coming from a Java background, and Java uses pointers a lot but hides them from you. C++ doesn't hide them at all. The consequence is that C++ has different syntax for explicitly dealing with pointers. Java got rid of all that and mostly used the regular, non-pointer syntax from C++ for dealing with pointers.

Java:                                  C++:

Player player = new Player();          Player *player = new Player();

Player player2;                        Player *player2 = nullptr;

** no equivilant in java **            Player player3;

player.foo();                          player->foo();

** no equivilant in java **            player3.foo();

** no equivilant in java **            *player;

** no equivilant in java **            &player2;

It's very important to understand the difference between working with pointers and working directly with an object:

Java:                                  C++:

Player a = new Player();               Player *a = new Player();
Player b = a;                          Player *b = a;
b.foo();                               b->foo();

In this code there's only a single object, and you can access it through either a or b and it doesn't make a difference, a and b are both pointers to the same object.

C++:

Player c = Player();
Player d = c;
d.foo();

In this code there are two objects. They are distinct, and doing something to d does not affect c.

If in Java you learned about the distinction between 'primitive' types like int and Object types like String then one way to think about it is that in C++ all objects are primitive. If we look back at your code and use this 'C++ objects are like Java primitives' rule you can maybe see better what's wrong:

Java:
int[] players = new int[1];
players[0] = new int(playerWidth); // huh???

That should make it clear that the right hand side of the assignment should simply be a Player value rather than a dynamic allocation of a new player object. For an int in java this looks like players[0] = 100;. Since Object types in Java are different Java doesn't have a way to write Object values the way you can write int values. But C++ does; players[0] = Player(playerWidth, playerHeight, 20, 1);


The second problem is that arrays in C are weird and C++ inherited that.

Pointers in C and C++ allow 'pointer arithmetic. If you have a pointer to an object you can add to or subtract from it and get a pointer to a different object. Java has nothing similar to this.

int x[2]; // create an array of two ints, the ints are 'adjacent' to one another
// if you take the address for the first one and 'increment' it
// then you'll have a pointer to the second one.

int *i = &x[0]; // i is a pointer to the first element
int *j = &x[1]; // j is a pointer to the second element

// i + 1 equals j
// i equals j - 1

Additionally the array index operator [] works on pointers. x[5] is equivalent to *(x+5). This means that pointers can be used as arrays, and that is idiomatic and expected in C and C++. In fact it's even baked into C++.

In C++ when you use new to dynamically allocate an object, e.g. new Player, you normally get a pointer to the type you specified. In this example you get Player *. But when you dynamically allocate an array, e.g. new Player[5], it's different. Instead of getting back a pointer to an array of five Players, you actually get back a pointer to the first element. This is just like any other Player *:

Player *p   = new Player;    // not an array
Player *arr = new Player[5]; // an array

The only thing that makes this pointer different is that when you do pointer arithmetic on it you get pointers to valid Player objects:

Player *x = p + 1;   // not pointing at a valid Player
Player *y = arr + 3; // pointing at the fourth array element

new and delete are hard to use correctly if you use them without protection. To demonstrate this:

int *x = new int;
foo();
delete x;

This code is error prone and probably wrong. Specifically, if foo() throws an exception then x is leaked.

In C++ whenever you acquire a responsibility, such as when you call new you acquire the responsibility to call delete at a later time, you should remember

R.A.I.I.
Responsibility* Acquisition Is Initialization

* More frequently people say 'resource acquisition is initialization', but resources are only one kind of responsibility. I was persuaded to use the latter term by Jon Kalb in one of his Exception Safe C++ talks.

R.A.I.I. means that whenever you acquire a responsibility, it should look like you're initializing an object; specifically you're initializing a special object who's purpose is to manage that responsibility for you. One example of such an type is std::unique_ptr<int> which will manage pointers to ints allocated with new:

C++:

std::unique_ptr<int> x(new int);
foo();
// no 'delete x;'

To manage your Player array you'd use std::unqiue_ptr like this:

std::unique_ptr<Player[]> players(new Player[1]);
players[0] = Player(playerWidth, playerHeight, 20, 1);

Now the unique_ptr will handle that allocation for you and you don't need to call delete yourself. (N.B. when you allocate an array you should give unique_ptr an array type; std::unique_ptr<Player[]>, and when you allocate anything else you use a non-array type, std::unique_ptr<Player>.)

Of course C++ has an even more specialized R.A.I.I. type for managing arrays, std::vector, and you should prefer that to using std::unique_ptr:

std::vector<Player> players(1);
players[0] = Player(playerWidth, playerHeight, 20, 1);

Or in C++11:

std::vector<Player> players { Player(playerWidth, playerHeight, 20, 1) };
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Wow this is some really great stuff. Really appreciate the comparisons between java and c++, it was hard to get my mind around the pointer concepts but you did an exceptional job illustrating it. Thank you –  Eric Smith Jan 16 '13 at 19:31
    
Well illustrated. I wouldn't call arrays in C/C++ wierd, though; they are logical and tied to a simple pointer arithmetic. Have to admit, though, pointers are tricky, and syntax like "5[array]" (yes, that is valid C/C++ syntax) only goes to show how tricky they can be! –  Helixirr Jul 20 '13 at 13:07
    
@Helixirr The weird things about arrays aren't so much anything to do with pointers, but all the inconsistencies and special cases; for example you can't return an array by value, if you try to declare an array value parameter then the language 'adjusts' it for you to something else, array objects aren't assignable, and many more. –  bames53 Jul 20 '13 at 13:52

Your types don't match. And it's no wonder, you're trying to store a Player* into an already-allocated Player!

Player* players = new Player[1];

This creates an array of length 1, containing an instantiated Player, and stores the whole thing into a Player*. The type of players[0] is going to be Player.

players[0] = new Player(...)

This attempts to create a new Player* and store it in the array. But the array contains Player objects. You should just say

players[0] = Player(...)

Alternatively, and I'm going to guess this is more appropriate for you, you should stop using new entirely, and use a std::vector.

std::vector<Player> players;
players.push_back(Player(playerWidth, playerHeight, 20, 1));
// or players.emplace_back(playerWidth, playerHeight, 20, 1);

Not only is this much easier to use, but you also don't have to remember to delete it later. When the std::vector goes out of scope, it will automatically destruct. Also, unlike your array, std::vector can contain any number of objects, so you can add new players or delete existing players at will.

There are other data structures as well that may possibly be more suited for you, depending on your exact use, but std::vector is a good starting point.

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1  
+1 for std::vector –  Cheers and hth. - Alf Jan 15 '13 at 19:45

The reason is, type of your variable

players[0]

is Player (object). However, operator "new" (new Player) returns a pointer (Player*)

If you want to have only one object, correct way to do it will be:

Player* player = new Player(playerWidth, playerHeight, 20, 1);

And don't forget in C++ you need to clean the mess after yourself - somewhere in the end call

delete player;

for every object you've created. C++ does not have Garbage Collector - meaning all manually created (by "new") objects stay until you manually delete them.

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no mention of vector? Or array? value semantics? unique_ptr? –  Mooing Duck Jan 15 '13 at 19:11
    
Easy, man, he's just starting :) –  DarkWanderer Jan 15 '13 at 19:12
    
I can throw whole boost/C++0x documentation into him, but this is not the stuff that helps to grasp basic concepts. –  DarkWanderer Jan 15 '13 at 19:13
2  
value semantics are a key part of C++. This answer merely shows how to make Java-like code compile in a C++ compiler, with no indication that there are far better and simpler ways. I'm not requesting all of boost/C++0x, but at least mention value semantics. RAII is bonus points. –  Mooing Duck Jan 15 '13 at 19:20

In Java, you do Foo f = new Foo();, giving you a dynamically allocated object who's lifetime is managed by the garbage collector.

Now, in C++, Foo* f = new Foo; looks similar and also gives you a dynamically allocated object (which you can access via the pointer f), but C++ doesn't have a built-in garbage collector. In most cases, the functional C++ equivalent is Foo f;, which gives you a local object that is destroyed when you leave the current function (via return or throw).

If you need dynamic allocation, use "smart pointers", which are actually classes that behave like pointers. In C++ 98, there is only std::auto_ptr and people often use boost::shared_ptr to complement it. In the newer C++ 11, there are std::unique_ptr and std::shared_ptr that achieve the same.

I hope this gives you some pointers in directions where you need to read a bit, but overall Juanchopanza gave a good advise: Don't use new unless you really need to. Good luck!

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In Java, when you use the keyword "new" you actually get back a pointer to an object. This is the only way to instantiate an object type in Java. So when you say you have an "Array of objects" in Java, it's more correct to say that you have an array of pointers to objects.

C++ does not hide the fact that objects are pointers. You can have a variable referencing an object, or you can have a variable referencing a pointer to an object.

In your example, you need to explicitly declare it an as an array of pointers to objects.

Players **players = new (Player*)[1];                         // Create an array of player pointers
players[0] = new Player(playerWidth, playerHeight, 20, 1);    // Create a single player

And while C++ allows you to explicitly create objects using the keyword new, you must be sure to cleanup your objects once you are done, otherwise they will never be deallocated (known as a memory leak).

This is one of the major differences between C++ and Java; Java's objects are garbage collected and the programmer doesn't have to worry about managing the lifetime of an object.

Once you are done, you will need to cleanup both the individual player that you allocated, as well as the array. Good rule of thumb is that every call to new should correspond to a call to delete.

delete players[0];  // delete the player pointed to by players[0]
delete[] players;   // syntax for deleting arrays

However, something interesting to note is that unlike Java, where objects are allocated on the heap, you can create objects on the stack in C++ as if they were primitive types (like int, float, char). This allows you to have objects that are locally scoped, as well as contiguously aligned in memory. There is no way to do this in Java.

If you allocate an array of objects this way, then the default constructor is called for each object in the array.

Player p;                           // This calls the default constructor and returns a Player object

Players *players = new Player[5];   // Create an array of player objects
players[0].playerWidth = 8;         // valid because the object has already been constructed

delete[] players; // don't forget to cleanup the array.
                  // no need to cleanup individual player objects, as they are locally scoped.

EDIT: As some others have mentioned, using a std::vector instead of an array is probably easier in your case (no need to worry about memory allocation) and is on the same order of performance as an array; however I think it is extremely important to become comfortable with the notion of pointers in C++ as they help you understand how memory is organized.

Here is the syntax for creating a vector of Player pointers.

std::vector<Player*> players(1); // Creates a vector of pointer to player with length 1
players[0] = new Player(playerWidth, playerHeight, 20, 1); // Create a new player object
delete players[0];                                         // delete the player

And the syntax for creating a vector of actual Player object instances (this one is the most preferred solution):

std::vector<Player> players(5); // Creates a vector of five player objects
players[0].playerWidth = 8; //already constructed, so we can edit immediately
//no cleanup required for the vector _or_ the players.
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"All ... objects are actually pointers to objects" sounds like infinite recursion ;-) Also, no mention of other (better!) ways to allocate? –  delnan Jan 15 '13 at 19:21

Here you have allocated some memory to store an array of one Player (not really useful but it's a first step).

Your variable "players" is now storing the address of the first (and only) slot in this array. Then by accessing the first Player with players[0], you are able to directly write/read in its memory and no more allocation is needed.

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