i'm self-teaching c++ and i get how pointers work. but the doc i'm using is quite literal and the examples don't really go into why or when pointers would be used. a couple of real world examples would help me retain the knowledge.
You use pointers when you want your objects to exist longer than the current stack. You can also use them to avoid copying objects into containers.
This is not an easy question to give a short and easy answer to, and I'm sure there's plenty of resources out there talking about pointers. Basically, whenever you'd like to use indirection (which may be even recursively) you need pointers.
Say for example a binary tree data structure, where each node have pointers to it's left and right sub trees, where either might a pointing to
You can't use anything BUT a pointer in this case, as it'd be an infinitely large structure.
This is not really a C++ matter, rather it is a C matter. For the beginner level, I would love to recommend the book Understanding Pointers in C
Pointers are useful when you need a function to return more than one variable. As an example, consider you are shopping at a grocery store. Each product has a name and a price. The name would be a string and the price a double. If there were a function called "buy", and you wanted to return both the name and price of the item, you might want to use a pointer.
Or like a array of functions (example):
Usage objects by pointers is in many cases is better:
If you have many objects and you must for example get it in a some arrange (eg. sort) you can use pointers for sort pointers to objects non objects:
For dynamic memory alocation in C language:
Pointers address the following issues:
Sometimes pointers are also used as handles. That is, if you want to allow client code to uniquely identify a chunk of data without caring (or knowing) what the data is, you cast the address of the data (the pointer) to int/some other type and pass it around as a handle. This is commonly found in APIs that offer handles to client code but don't allow client code access to the real data (see use of WinAPI's HANDLE, HWND and so on - those are pointers in the internal implementation, but you don't know - or care - what the actual data is in order to use it).
A pointer can be considered a simple variable, but instead of saving a value it saves an adress to the position of the memory that stores a value.
Think the memory as a block of drawers and in each drawer you can put a value, to make it easier to find the values, you numerus the drawers. So, a position of memory would be a drawer and the block would be the full memory.
So, when you create a pointer, for example:
You are referring to the drawer which is labelled with the number 0 and contains an integer value, now you may think, ok, but, how can I get that value? Well, it's simple:
By the same way you can store a new value on that drawer (memory address):
Now comes the fun, the block of drawers is magic, and a drawer can take you to another drawer of the block, if we label them with the same number, the value that one stores is the same in the other:
And what happens? That "drawer_copy", which is referring to the address 0 as "drawer" allows you to access to the integer value 15.
We can also save the address of a normal variable, we use the "&" prefix to get that adress:
If we do this now:
"*drawer" will return a 5.
As you can see, pointers allow the user to have more control on the memory and to have reserved memory permanently, once you have declared a pointer you can preserve an address and access to it whenever you want. :)
Okay, I've seen so many terrible responses that I feel myself obligated to add yet another one.
First things first: we are talking C++ here. So many C uses are completely invalidated.
Terrible uses of pointers
You should learn RAII: this example is completely unsafe in the face of exception
Rule of Thumb: if you see
Use references whenever possible
Whenever the passing
Good uses of pointers:
this is equivalent to:
but quite less verbose.
The use of a bare pointer as the return type of the
There is a sound reason: taking advantage of covariant return types for the overloading of virtual methods. This allows us to write:
Thus taking full advantage, when cloning from a
It is up to the programmer to take care of the allocated memory unfortunately, so it must be used in conjunction with Smart Containers: