What is the meaning of Pointers? Is the topic of this article.
Pointers are basically the same as any other variable. However, what is different about them is that instead of containing actual data, they contain a pointer to the memory location where information can be found. This is a very important concept. Many programs and ideas rely on pointers as the basis of their design, linked lists for example.
Getting Started
How do I define a pointer? Well, the same as any other variable, except you add an asterisk before its name. So, for example, the following code creates two pointers, both of which point to an integer:
cpp code
int* pNumberOne;
int* pNumberTwo;
Notice the "
p" prefix in front of the two variable names? This is a convention used to indicate that the variable is a pointer. Now, let's make these pointers actually point to something:
cpp code
pNumberOne = &some_number;
pNumberTwo = &some_other_number;
The
& (ampersand) sign should be read as "the address of" and causes the address in memory of a variable to be returned, instead of the variable itself. So, in this example,
pNumberOne is set to equal the address of some_number, so
pNumberOne now points to some_number.
Now if we want to refer to the address of some_number, we can use pNumberOne. If we want to refer to the value of some_number from pNumberOne, we would have to say *pNumberOne. The * dereferences the pointer and should be read as "the memory location pointed to by," unless in a declaration, as in the line int
*pNumber.
An ExamplePhew! That's a lot to take in. I'd recommend that if you don't understand any of those concepts, to give it another read through. Pointers are a complex subject and it can take a while to master them. Here is an example that demonstrates the ideas discussed above. It is written in C, without the C++ extensions.
cpp code
#include <stdio.h>
void main()
{
// declare the variables:
int nNumber;
int *pPointer;
// now, give a value to them:
nNumber = 15;
pPointer = &nNumber;
// print out the value of nNumber:
printf("nNumber is equal to : %d\n", nNumber);
// now, alter nNumber through pPointer:
*pPointer = 25;
// prove that nNumber has changed as a result of the above by
// printing its value again:
printf("nNumber is equal to : %d\n", nNumber);
}
Read through and compile the above code sample. Make sure you understand why it works. Then, when you are ready,
If you can spot the fault in the program below: cpp code
#include <stdio.h>
int *pPointer;
void SomeFunction();
{
int nNumber;
nNumber = 25;
// make pPointer point to nNumber:
pPointer = &nNumber;
}
void main()
{
SomeFunction(); // make pPointer point to something
// why does this fail?
printf("Value of *pPointer: %d\n", *pPointer);
}
This program firstly calls the SomeFunction function, which creates a variable called
nNumber and then makes the pPointer point to it. Then, however, is where the problem is. When the function leaves, nNumber is deleted because it is a local variable. Local variables are always deleted when execution leaves the block they were defined in. This means that when SomeFunction returns to main(), the variable is deleted. So pPointer is pointing at where the variable used to be, which no longer belongs to this program. If you do not understand this, it may be wise to read back over on local and global variables, and on scope. This concept is also important.
So, how can the problem be solved? The answer is by using a technique known as dynamic allocation. Please be aware that this is different between C and C++. Since most developers are now using C++, this is the dialect that the code below is using.
Dynamic AllocationDynamic allocation is perhaps the key to pointers. It is used to allocate memory without having to define variables and then make pointers point to them. Although the concept may appear confusing, it is really simple. The following code demonstrates how to allocate memory for an integer:
cpp code
int *pNumber;
pNumber = new int;
The first line declares the pointer,
pNumber. The second line then allocates memory for an integer and then makes pNumber point to this new memory. Here is another example, this time using a double:
cpp code
double *pDouble;
pDouble = new double;
The formula is the same every time, so you can't really fail with this bit. What is different about
dynamic allocation, however, is that the memory you allocate is not deleted when the function returns, or when execution leaves the current block. So, if we rewrite the above example using dynamic allocation, we can see that it works fine now:
cpp code
#include <stdio.h>
int *pPointer;
void SomeFunction()
{
// make pPointer point to a new integer
pPointer = new int;
*pPointer = 25;
}
void main()
{
SomeFunction(); // make pPointer point to something
printf("Value of *pPointer: %d\n", *pPointer);
}
Read through and compile the above code sample. Make sure you understand why it works. When SomeFunction is called, it allocates some memory and makes
pPointer point to it. This time, when the function returns, the new memory is left intact, so
pPointer still points to something useful. That's it for dynamic allocation! Make sure you understand this, and then read on to learn about the fly in the ointment, and why there is still a serious error in the code above.
Get and Remove Memory There's always a complication and this one could become quite serious, although it's very easy to remedy. The problem is that although the memory that you allocate using dynamic allocation is conveniently left intact, it actually never gets deleted automatically. That is, the memory will stay allocated until you tell the computer that you've finished with it. The upshot of this is that if you don't tell the computer that you've finished with the memory, it will be wasting space that other applications or other parts of your application could be using. This eventually will lead to a system crash through all the memory being used up, so it's pretty important.
How to free a memory :cpp code
delete pPointer;
That's all there is to it. You have to be careful, however, that you pass a valid pointer, i.e. that is a pointer that actually points to some memory you've allocated and not just any old rubbish. Trying to delete memory that's already been freed is dangerous and can lead to your program crashing. So here is the example again, updated this time so it doesn't waste any memory:
cpp code
#include <stdio.h>
int *pPointer;
void SomeFunction()
{
// make pPointer point to a new integer
pPointer = new int;
*pPointer = 25;
}
void main()
{
SomeFunction(); // make pPointer point to something
printf("Value of *pPointer: %d\n", *pPointer);
delete pPointer;
}
One line difference is all it took, but this line is essential. If you don't delete the memory, you get what is known as a "
memory leak," where memory is gradually leaking away and can't be reused unless the application is closed.
Sending Pointers to FunctionsThe ability to pass pointers to functions is very useful, but very easy to master. If we were to make a program that takes a number and adds five to it, we might write something like the following:
cpp code
#include <stdio.h>
void AddFive(int Number)
{
Number = Number + 5;
}
void main()
{
int nMyNumber = 18;
printf("My original number is %d\n", nMyNumber);
AddFive(nMyNumber);
printf("My new number is %d\n", nMyNumber);
}
However, the problem with this is that the Number referred to in AddFive is a copy of the variable
nMyNumber passed to the function, not the variable itself. Therefore, the line Number = Number + 5 adds five to the copy of the variable, leaving the original variable in main() unaffected. Try running the program to prove this.
To get around this problem, we can pass a pointer to where the number is kept in memory to the function, but we'll have to alter the function so that it expects a pointer to a number, not a number. To do this, we change
void AddFive(int Number) to
void AddFive(int* Number), adding the asterisk. Here is the program again, with the changes made. Notice that we have to make sure we pass the address of nMyNumber instead of the number itself? This is done by adding the & sign, which (as you will recall) is read as "the address of."
cpp code
#include <stdio.h>
void AddFive(int* Number)
{
*Number = *Number + 5;
}
void main()
{
int nMyNumber = 18;
printf("My original number is %d\n", nMyNumber);
AddFive(&nMyNumber);
printf("My new number is %d\n", nMyNumber);
}
Try coming up with an example of your own to demonstrate this. Notice the importance of the * before Number in the AddFive function? This is needed to tell the compiler that we want to add five to the number pointed to by the variable Number, rather than add five to the pointer itself. The final thing to note about functions is that you can return pointers from them as well, like this:
cpp code
int * MyFunction();
In this example,
MyFunction returns a pointer to an integer.
Pointers to ClassesThere are a couple of other caveats with pointers, one of which is structures or classes. You can define a class as follows:
cpp code
class MyClass
{
public:
int m_Number;
char m_Character;
};
Then you can define a variable of type
MyClass as follows:
cpp code
MyClass thing;
You should already know this. If not, try reading up on this area. To define a pointer to MyClass, you would use:
cpp code
MyClass *thing;
As you would expect. Then you would allocate some memory and make this pointer point to the memory:
cpp code
thing = new MyClass;
This is where the problem comes in: how then would you use this pointer? Well, normally you would write'thing.
m_Number, but you can't with a pointer because thing is not a MyClass, but a pointer to it. So, thing itself does not contain a variable called m_Number; it is the structure that it points to that contains m_Number. Therefore we must use a different convention. This is to replace the . (
dot) with a
-> (dash followed by a greater than sign). An example showing this is below:
cpp code
class MyClass
{
public:
int m_Number;
char m_Character;
};
void main()
{
MyClass *pPointer;
pPointer = new MyClass;
pPointer->m_Number = 10;
pPointer->m_Character = 's';
delete pPointer;
}
Pointers to ArraysYou can also make pointers that point to arrays. This is done as follows:
cpp code
int *pArray;
pArray = new int[6];
This will create a pointer, pArray, and make it point to an array of six elements. The other method, not using dynamic allocation, is as follows:
cpp code
int *pArray;
int MyArray[6];
pArray = &MyArray[0];
Note that, instead of writing
&MyArray[0], you can simply write
MyArray. This, of course, only applies to arrays and is a result of how they implemented in the C/C++ language. A common pitfall is to write
pArray = &MyArray;, but this is incorrect. If you write this, you will end up with a pointer to a pointer to an array (no typo), which is certainly not what you want.
Using Pointers to ArraysOnce you have a pointer to an array, how do you use it? Well, let's say you have a pointer to an array of ints. The pointer will initially point to the first value in the array, as the following example shows:
cpp code
#include <stdio.h>
void main()
{
int Array[3];
Array[0] = 10;
Array[1] = 20;
Array[2] = 30;
int *pArray;
pArray = &Array[0];
printf("pArray points to the value %d\n", *pArray);
}
To make the pointer move to the next value in the array, we can say
pArray++. We can also, as some of you probably guessed by now, say
pArray + 2, which would move the array pointer on by two elements. The thing to be careful of is that you know the what the upper bound of the array is (3 in this example), because the compiler cannot check that you have not gone past the end of array when you are using pointers. You could easily end up crashing the system that way. Here is the example again, this time showing the three values that we set:
cpp code
#include <stdio.h>
void main()
{
int Array[3];
Array[0] = 10;
Array[1] = 20;
Array[2] = 30;
int *pArray;
pArray = &Array[0];
printf("pArray points to the value %d\n", *pArray);
pArray++;
printf("pArray points to the value %d\n", *pArray);
pArray++;
printf("pArray points to the value %d\n", *pArray);
}
You can also subtract values, so
pArray - 2 is 2 elements from where
pArray is currently pointing. Make sure, however, that you add or subtract to the pointer and not to its value. This kind of manipulation using pointers and arrays is most useful when used in loops, such as the for or while loops.
Note also that if you have a pointer to a value, e.g.
int* pNumberSet, you can treat it as an array. For example,
pNumberSet[0] is equivalent to
*pNumberSet; similarly,
pNumberSet[1] is equivalent to
*(pNumberSet + 1).
One final word of warning for arrays is that if you allocate memory for an array using new, as in the following example:
cpp code
int *pArray;
pArray = new int[6];
It must be deleted using the following: cpp code
delete[] pArray;
Notice the
[] after delete. This tells the compiler that it is deleting a whole array and not just a single item. You must use this method whenever arrays are involved; otherwise, you will end up with a memory leak.
Last Words
One final note: you must not delete memory that you did not allocate using new, as in the following example:
cpp code
void main()
{
int number;
int *pNumber = number;
delete pNumber; // wrong - *pNumber wasn't allocated using new.
}
Common Questions and FAQQ: Why do I get "symbol undefined" errors on new and delete?A: This is most likely caused by your source file being interpreted by the compiler as being a plain C file. The new and delete operators are a new feature of C++. This is usually remedied by ensuring that you are using a *.cpp extension on your source code files.
Q: What's the difference between new and malloc?A: new is a keyword only present in C++ and is now the standard way (other than using Windows' memory allocation routines) to allocate memory. You should never use
malloc within a C C++ application unless absolutely necessary. Because
malloc is not designed for the object-oriented features of C++, using it to allocate memory for classes will prevent the constructor of the class being called, as just one example of the problems that can arise. As a result of the problems that arise from the use of malloc and free, and because they are now for all intents and purposes obsolete, they are not discussed in any detail in this article. I would discourage their use wherever possible.
Q: Can I use free and delete together?A: You should free memory with the equivalent routine to that used to allocated it. For instance, use free only on memory allocated with
malloc, delete only on memory allocated with new and so on.
References
References are, to a certain degree, out of the scope of this article. However, since I've been asked many times by people reading this about them, I will discuss them briefly. They are very much related to pointers in that, in many cases, they can be used as a simpler alternative. If you recall from above, I mentioned that the ampersand (
&) is read as "the address of" unless in a declaration. In the case of its presence in a declaration such as that shown below, it should be read as "a reference to."
cpp code
int& Number = myOtherNumber;
Number = 25;
The reference is like a pointer to
myOtherNumber, except that it is automatically dereferenced. So, it behaves just as it were the actual value type rather than a pointer type. The equivalent code to this, using pointers, is shown below:
cpp code
int* pNumber = &myOtherNumber;
*pNumber = 25;
The other difference between pointers and references is that you cannot "
reseat" a reference. That is to say that you cannot change what it is pointing to after its declaration. For instance, the following code would output "20."
cpp code
int myFirstNumber = 25;
int mySecondNumber = 20;
int &myReference = myFirstNumber;
myReference = mySecondNumber;
printf("%d", myFristNumber);
When in a class, the value of the reference must be set by the constructor in the following way:
cpp code
CMyClass::CMyClass(int &variable) : m_MyReferenceInCMyClass(variable)
{
// constructor code here
}
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