Arrays Revealed

Arrays Revealed

Introduction
Arrays are the built-in containers of C and C++. This article assumes the reader has some experiece with
arrays and array syntax but is not clear on a )exactly how multi-dimensional arrays work, b) how to call
a function with a multi-dimensional array, c) how to return a multi-dimensional array from a function,
or d) how to read and write arrays from a disc file.

Note to C++ programmers: You should be using vectors instead of arrays. The protective code you need
to write around your array is a duplication of the protective code written around the array in the STL.
The STL just calls their array plus managing code a vector.

Note to C programmers: Everything in this article conforms to ANSI-C with the exception of heap allocations.
The examples use the C++ new operator where a C programmer would call malloc().


How to Define Arrays
First, there are only one-dimensional arrays in C or C++. The number of elements is put between brackets:


That is an array of 5 elements each of which is an int.



won't compile. You need to declare the number of elements.

Second, this array:


is still an array of 5 elements. Each element is an array of 10 int.



is still an array of 5 elements. Each element is an array of 10 elements where each element is an array of 15 int.




won't compile. You need to declare the number of elements.

Third, the name of an array is the address of element 0


Here array is the address of array[0]. Since array[0] is an int, array is the address of an int. You can assign the name array to an int*.



Here array is the address of array[0]. Since array[0] is an array of 10 int, array is the address of an array of 10 int. You can assign the name array to a pointer to an array of 10 int:


Fourth, when the number of elements is not known at compile time, you create the array dynamically:



In each case value is the number of elements. Any other brackets only describe the elements.

Using an int** for an array of arrays is incorrect and produces wrong answers using pointer arithmetic. The compiler knows this so it won't compile this code:



new returns the address of an array of 10 int and that isn't the same as an int**.

Likewise:


new returns the address of an array of 10 elements where each element is an array of 15 int and that isn't the same as an int***.

With the above in mind this array:

has a memory layout of

0 1 2 3 4 5 6 7 8 9

Wheras this array:

has a memory layout of

0 1 2 3 4 5 6 7 8 9

Kinda the same, right?

So if your disc file contains

0 1 2 3 4 5 6 7 8 9

Does it make a difference wheher you read into a one-dimensional array or a two-dimensional array? No.

Therefore, when you do your read use the address of array[0][0] and read as though you have a
one-dimensional array and the values will be in the correct locations.

Passing Multi-dimensional Arrays to Functions

This array:




can be passed to a function if the argument to func() is a pointer to a [4][5] array:


But if the func argument is a pointer to an [5] array of int, you need to pass the &arr[0][0]:


But if the func argument is a pointer to an int, you need to pass the &arr[0][0][0]:


As you omit dimensions, notice that you need to add arguments to func() since the "array-ness" is
lost on the call. This is called decay of array and it occurs whenever an array is passed
to a function. From inside the function all you see is an address and not an array. That forces you to pass
the number of elements in the "dimensions".

Returning Multi-dimensional Arrays from Functions

Returning an array from a function only has meaning if the array was created by the function. Otherwise,
no return is necessary since an existing array is passed by the address. However, if the function has
created the array on the heap, you can return the address of element 0.

The problem here is that you can't use the function return type unless you a) return a type or
b) return a pointer to a type. That is, you cannot return a pointer to an array since an array is not
a type. So, if you create an array of int you can return the array as an int*:


This does not work when you create a multi-dimensional array:


In this case you would pass in the address of a pointer to an array of 5 int:


Finally, as was stated at the beginning of this article: There are no multi-dimensional arrays in C++.
Therefore, the function could just create a one-dimensional array of the correct number of elements and return
the address of element 0. In this case, element 0 is a type and you can use the return type of a function
to return a pointer to a type. Then the calling function could typecast the return so the array can be
used with muliple dimensions:




Copyright 2008 Buchmiller Technical Associates North Bend WA USA

PERFECT............

What an article.......must read for every C newbie like me....
Thanks for such a nice article

Very good article!

If you could write some examples that we could copy and paste them to a compiler, just to see the result, it would be nice!

Quote: Very good article! If you could write some examples that we could copy and paste them to a compiler, just to see the result, it would be nice!

How do you mean? All of the code in the article can be compiled.

Quote: How do you mean? All of the code in the article can be compiled.

Yes, but after compilation, they don't return any results to the screen (propably because there are no printf). And at least for me who just started reading about C is difficult to place a printf on examples with pointers and arrays, etc.
...or am I doing sthg wrong and I don't get results??????

On a minor point, early in the article you say that int a [ ] [10] won't compile. I assume you mean when the code is declaring the array, because it is permissable to call a function which includes an array as its arguement like void print( int a [ ] [10 ]..... or so my book says.
Thanks for your article

Quote: On a minor point, early in the article you say that int a [ ] [10] won't compile. I assume you mean when the code is declaring the array, because it is permissable to call a function which includes an array as its arguement like void print( int a [ ] [10 ]..... or so my book says. Thanks for your article

Your book is correct. As a function argument int a [ ] [10 ] is a pointer. As an array definition it is incomplete because it lacks the number of elements in the array. It is the array definition that is referred to in the article.

Thank you .... What a wonderful article !!! I should have read it a couple months back :(

Thank you for your guide!

Correct me if I am wrong, but shouldn't the following line:

int (*ptr)[10];

be interpreted as "an array of 10 pointers to int" and not as "a ptr to an array of 10 ints"? I thought that the bracket operator had higher precedence than dereference (hence the parenthesis around *ptr).

Quote: Thank you for your guide! Correct me if I am wrong, but shouldn't the following line: int (*ptr)[10]; be interpreted as "an array of 10 pointers to int" and not as "a ptr to an array of 10 ints"? I thought that the bracket operator had higher precedence than dereference (hence the parenthesis around *ptr).

An array of 10 pointers to int would be:

int* ptr[10];

The parentheses are needed to define ptr as a pointer to an array of 10 rather than ptr as an array of 10.