By reading some details about pointers and arrays in C I got a little confused. On the one hand, the array can be seen as a data type. On the other hand, the array tends to be an unmodifiable lvalue. I imagine that the compiler will do something like replacing the array's identifier with a constant address and an expression for calculating the position given by the index at runtime.

myArray[3] -(compiler)-> AE8349F + 3 * sizeof(<type>)

When saying that an array is a data type, what does this exactly mean? I hope you can help me to clarify my confused understanding of what an array really is and how it is treated by the compiler.

  • 2
    An array is an object that encapsulates potentially more than one object in a contiguous block of memory. Arrays are related to pointers, but I think that's really another question, which you should read about here.
    – user529758
    Jul 23, 2013 at 20:50
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    Your imagination appears to be correct (at least for popular C implementations). What exactly is the question?
    – Carl Norum
    Jul 23, 2013 at 20:55
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    @HotLicks: Array objects are just as "real" as any other type of object. An array of N foos has a size of N * sizeof (foo), for example. Array expressions, on the other hand, behave oddly, in ways thoroughly explained by section 6 of the comp.lang.c FAQ, which H2CO3 linked to above. Jul 23, 2013 at 21:06
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    Your title says C++, your question and tags say only C. Are you asking about C++ or not?
    – Ben Voigt
    Jul 23, 2013 at 21:25
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    @HotLicks: All type information is compiler fiction. The hardware doesn't have types.
    – Ben Voigt
    Jul 23, 2013 at 21:26

2 Answers 2


When speaking about that an array is a data type, what does this exactly mean?

A data type is a set of data with values having predefined characteristics. Examples of data types are: integer, floating point unit number, character, string, and pointer

An array is a group of memory locations related by the fact that they all have the same name and the same type.

If you are wondering why array is not modifiable then best explanation I have ever read is;

C didn't spring fully formed from the mind of Dennis Ritchie; it was derived from an earlier language known as B (which was derived from BCPL).1 B was a "typeless" language; it didn't have different types for integers, floats, text, records, etc. Instead, everything was simply a fixed length word or "cell" (essentially an unsigned integer). Memory was treated as a linear array of cells. When you allocated an array in B, such as

auto V[10];

the compiler allocated 11 cells; 10 contiguous cells for the array itself, plus a cell that was bound to V containing the location of the first cell:

V:  |    | -----+
    +----+      |
     ...        |
    +----+      |
    |    | <----+
    |    |
    |    |      
    |    |

When Ritchie was adding struct types to C, he realized that this arrangement was causing him some problems. For example, he wanted to create a struct type to represent an entry in a file or directory table:

struct {
  int inumber;
  char name[14];

He wanted the structure to not just describe the entry in an abstract manner, but also to represent the bits in the actual file table entry, which didn't have an extra cell or word to store the location of the first element in the array. So he got rid of it - instead of setting aside a separate location to store the address of the first element, he wrote C such that the address of the first element would be computed when the array expression was evaluated.

This is why you can't do something like

int a[N], b[N];
a = b;

because both a and b evaluate to pointer values in that context; it's equivalent to writing 3 = 4. There's nothing in memory that actually stores the address of the first element in the array; the compiler simply computes it during the translation phase.

1. This is all taken from the paper The Development of the C Language

For more detail you may like to read this answer.

EDIT: For more clarity; Difference between modifiable l-value, non-modifiable l-value & r-value (in short);

The difference among these kinds of expressions is this:

  • A modifiable l-value is addressable (can be the operand of unary &) and assignable (can be the left operand of =).
  • A non-modifiable l-value is addressable, but not assignable.
  • An r-value is neither addressable nor assignable.
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    @Sam To sort of tie this back to your original example, say you have <type> foo[7]; myArray = foo; then you'll get a compiler error on the second line (myArray = foo;). This is what they mean by an array being an unmodifiable lvalue*. Of course you can assign to myArray[i] (for any constant or variable i), but you cannot assign myArray directly. Think about what it means compiled... by your example, myArray = foo; would be 0xAE8349F = 0xDEADBEEF; (assuming foo is located at address 0xDEADBEEF). A constant cannot be an lvalue for any assignment operator. Jul 23, 2013 at 21:58
  • As for the data type bit, I think that is essentially referring to the fact that you can declare variables of that type (e.g., myArray has the type "array of 3 <type>" - or <type>[3] for short). You can therefore also use arrays as parameter types to functions, and so forth. There is a subtle distinction between a parameter type <type>[3] and a parameter type <type>*. (Someone please double check my accuracy, and also see if I'm really answering the question that was asked here...) Jul 23, 2013 at 22:05
  • An "lvalue" is a bit more than just where it can go, and most simply it's an expression which refers to an object. In terms of operators, you would normally hear it described as something that can go on the left hand side of specifically the assignment operator, not any operator whatsoever, but obviously unmodifiable lvalues can't.
    – Crowman
    Jul 23, 2013 at 22:11
  • @haccks: No, sorry, I was responding to DaveLillethun's "'lvalue' just means that it can appear to the left side of an operator".
    – Crowman
    Jul 23, 2013 at 22:14
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    @DaveLillethun: The names "lvalue" and "rvalue" refer specifically to the left and right sides of an assignment, not of any operator in general. Given 2 + 3, neither 2 nor 3 is an lvalue. The exact definition of "lvalue" in the C standard has changed in each version, but basically it's an expression that (potentially) designates an object. Jul 23, 2013 at 22:34

An array is a contiguous block of memory. This means it's laid out in memory sequentially. Let's say we define an array like:

int x[4];

Where sizeof(int) == 32 bits.

This will be laid out in memory like this (picking an arbitrary starting address, let's say 0x00000001)

0x00000001 - 0x00000004
[element 0]
0x00000005 - 0x00000008
[element 1]
0x00000009 - 0x0000000C
[element 2]
0x0000000D - 0x00000010
[element 3]

You're correct that the compiler replaces the identifier. Remember (if you've learned this. If not, then you're learning something new!) that an array is essentially a pointer. In C/C++, the array name is a pointer to the first element of the array (or a pointer pointing to address 0x00000001 in our example). By doing this:

std::cout << x[2];

You're telling the compiler to add 2 to that memory address, which is pointer arithmetic. Let's say instead you use a variable to index:

int i = 2;
std::cout << x[i];

The compiler sees this:

int i = 2;
std::cout << x + (i * sizeof(int));

It basically multiplies the size of the datatype by the given index and adds that to base address of the array. The compiler basically takes the index-of operator [] and converts it to addition with a pointer.

If you really want to spin your head around this, consider this code:

std::cout << 2[x];

This is completely valid. If you can figure out why, then you've got the concept down.

  • Please, there are lots of small inaccuracies in here which together kill the answer as far as reliability goes. For example x[2] does not add 2 to the address of x. Secondly an array is only functionally a continous block of memory, but that does not need to mean elements follow each other without gaps (think alignment).
    – user268396
    Jul 23, 2013 at 21:41
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    @user268396: The elements follow each other without gaps, the padding is part of the element. Jul 23, 2013 at 21:44
  • You are of course correct. My typing isn't much better than the answer's but the point stands that the "picture" as described in the answer about memory addresses of the elements in the array (vs what you actually get) does not account for it. Not accounting for padding/alignment issues tends to introduce nasty bugs once people start doing clever things ...
    – user268396
    Jul 23, 2013 at 21:51
  • @BartekBanachewicz How about you read the rest of the answer which further elaborates?
    – MGZero
    Jul 23, 2013 at 22:19
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    @MGZero: Then explain why int arr[100]; sizeof arr doesn't give you the size of a pointer. An array name is converted to a pointer to the first element in most contexts. Please read section 6 of the comp.lang.c FAQ. Jul 23, 2013 at 22:36

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