10
int a[10];
int b[10];

a = b; // illegal

typedef struct {
    int real;
    int imag;
    } complex;

complex c,d;
c = d; //legal

[I realize that a and b are addresses in 1st case,but symbols in 2nd case]

7
  • 7
    Because in C arrays aren't lvalues. That's just what the language is.
    – cnicutar
    Jan 20, 2012 at 9:21
  • No, a and b are not "bare addresses". The closest things to bare addresses are void * or intptr_t. a and b have type int[10]. Jan 20, 2012 at 9:36
  • @cnicutar: A counterexample: int foo[10]; &foo; Jan 20, 2012 at 9:56
  • 1
    @cnicutar an array IS a lvalue. An array is not a modifiable lvalue.
    – ouah
    Jan 20, 2012 at 10:25
  • @ouah: An array is an object; an lvalue is a kind of expression. An array expression can be (and usually is) an lvalue, but it's implicitly converted to a non-value pointer expression in most contexts. Jan 20, 2012 at 10:59

7 Answers 7

13

For historical info, this may be interesting: http://cm.bell-labs.com/who/dmr/chist.html

In B, declaring an array would set aside memory for the array, just as C does, but the name supplied for the variable was used to define a pointer to the array. Ritchie changed this in C, so that the name "is" the array but can decay to a pointer when used:

The rule, which survives in today's C, is that values of array type are converted, when they appear in expressions, into pointers to the first of the objects making up the array.

This invention enabled most existing B code to continue to work, despite the underlying shift in the language's semantics. The few programs that assigned new values to an array name to adjust its origin—possible in B and BCPL, meaningless in C—were easily repaired.

If at that very early stage, Ritchie had defined a = b to copy the array, then the code he was trying to port from B to C would not have been as easily repaired. As he defined it, that code would give an error, and he could fix it. If he'd made C copy the array, then he would have silently changed the meaning of the code to copy the array rather than reseating the name being used to access an array.

There's still the question, "why hasn't this feature been added in the 40 years since", but I think that's why it wasn't there to start with. It would have been effort to implement, and that effort would actually have made that early version of C worse, in the sense of being slightly harder to port B and BCPL code to C. So of course Ritchie didn't do it.

0
5

Because C says you can't, it says "A modifiable lvalue is an lvalue that does not have array type, does not have an incomplete type", so an array can't be assigned to.

Moreover, When you use the name of an array in a value context likea = b; , both the names a and b mean &a[0] and &b[0]. Often referred to as an array "decaying" to a pointer.

However, arrays are not pointers, so trying to assign an array by using pointers wouldn't make sense.

1
  • Ok. I do understand that part. Language authors could've choosen behaviour so that array_var with out address operator would mean array as a whole just like struct_var with out & represents the whole structure. assignment might have been possible then!
    – Hari
    Jan 20, 2012 at 10:14
4

The first thing to understand is that arrays are not pointers. Read section 6 of the comp.lang.c FAQ. I'll wait.

...

Ok, done? No, go back and read the whole thing.

...

Great, thanks.

Generally speaking, arrays in C are second class citizens. There are array types, and array objects, and even array values, but arrays are almost always manipulated via pointers to their elements.

This requires a bit more work for the programmer (as you've seen, you can't just assign arrays), but it also gives you more flexibility. Programs that deal with arrays usually need to deal with arrays of different sizes, even sizes that can't be determined until execution time. Even if array assignment were permitted, an array of 10 ints and an array of 20 ints are of different and incompatible types. If you have a fixed-size array, as in the code in your question, it's common for only some of the elements to be currently relevant; you might have a 10-element array, but you're only currently using the first 5 elements. Processing such an array element-by-element makes it easier to process only the elements that are currently active (something you have to keep track of yourself).

For a struct, on the other hand, the number and types of the members are determined when you define the type. You can't traverse the members of a struct by advancing a pointer, as you would for an array, since the members are typically of different types. Arrays and structures are different things, and they have different sets of operations that make sense for them.

There are a couple of rules in the language that try to make it easier to do this, namely:

  • An array expression, in most but not all contexts, is implicitly converted to a pointer to the array's first element. The exceptions are:
    • When the array expression is the operand of the & (address) operator;
    • When it's the operand of sizeof; and
    • When it's a string literal in an initializer, used to initialize an array object.)
  • A declared array parameter, as in int func(char s[]); is adjusted to a pointer parameter: int func(char *s);.

(One could argue that these rules cause more confusion than they prevent, but that's the way the language is defined.)

Now I suppose the language could have been defined, or could be redefined, so that array assignment is permitted in cases where it makes sense:

int a[10];
int b[10];
/* ... */
a = b; /* Why not? */.

Perhaps such a change could even be made without breaking existing code. But that would require another special case for the array-to-pointer conversion rule. And it would only be useful in the case of fixed-size arrays like a and b, which though they're quite common in introductory programming exercises, are not as common in production code.

3

The main reason is of course the Standard. On the assignment operator constraint it says:

(C99, 6.5.16p2) "An assignment operator shall have a modifiable lvalue as its left operand"

where it defines a modifiable lvalue as

(C99, 6.3.2.1p1) "A modifiable lvalue is an lvalue that does not have array type, [...]".

So assigning to arrays is not permitted.

But the main reasons are historical reasons at the times where array copy was considered not appropriate for the hardware (the old PDP systems). Not that also in the first versions of C, the assignment of structure types objects was also not allowed. It was later added to the language but for the array to many parts of the language would have been needed to be changed to allow to assign to arrays.

0
-1

An array name is a const pointer so you can't change what it is pointing to.

Assuming that you meant c = d on the last line is legal, it's simply copying a non-const variable to another non-const variable, which is perfectly legal.

3
  • 2
    No, an array is not a pointer, it simply decays into one in certain contexts. Jan 20, 2012 at 9:32
  • @BlagovestBuyukliev: He did write array name, not array. I think downvoting is a bit harsh. Especially since all the subtle differences between arrays and pointers in C is an advanced topic. Discussing it with a beginner who is struggling to understand pointers, likely yields limited pedagogic value.
    – Lundin
    Jan 20, 2012 at 9:47
  • @Lundin: IMO, it's important to understand the distinction between an array and a pointer at the earliest possible stage; the number of questions on StackOverflow about e.g. passing multidimensional arrays into functions, etc. attests to that! Jan 20, 2012 at 9:49
-1

a is actually the "pointer" to the first element of array and it's a constant "pointer", so you are trying to assign an l-"pointer".

you can achieve what are you trying to do by :

struct arraystruct
{
  int t[10];
};


struct arraystruct a,b;

a=b;

EDIT:well i forgot to mention that there are a few exceptions where an array should not be considered as a pointer:

-you can use sizeof(array) but you cannot use sizeof(pointer)

-array of literal string

-a and &a are the same

1
  • @OliCharlesworth: But in this context, a decays into a struct arraystruct* const, since a is used in an expression. So the answer isn't really incorrect, just simplified.
    – Lundin
    Jan 20, 2012 at 9:55
-2

That is because the kind of array you are using is a so-called static array, ie. the memory for it is on the stack. If you would use dynamic arrays (with pointers) your assignment would be legal (but a memory leak would be possible). This would be a shallow copy.

See also Static array vs. dynamic array in C++

6
  • A "dynamic array" is not really an array in the terms of the language, but rather a pointer to a dynamically-allocated block of memory. Jan 20, 2012 at 9:37
  • @BlagovestBuyukliev: How can you tell? I would say it depends on how the pointer used with malloc was declared. If it was done like this int (*array)[10] = malloc(10*sizeof(int)); then I would certainly consider it an array in the terms of the language. Furthermore, these comments aren't helping the OP.
    – Lundin
    Jan 20, 2012 at 9:57
  • @Lundin: no, your example array is still a pointer to an array, and not an array itself. sizeof(array) will give you the size of a pointer, rather than 10 * sizeof(int). Jan 20, 2012 at 10:00
  • @BlagovestBuyukliev: I meant that in my example, the contents of what the pointer points at could only be regarded as an array, and not as "a block of memory". The name "array" for the array pointer was perhaps a bad choice.
    – Lundin
    Jan 20, 2012 at 10:03
  • @Lundin, isn't int (*array)[10] = malloc(10*sizeof(int)); missing a *? As I understand it, this code creates a static array of 10 pointers to int values, and as such should be int (*array)[10] = malloc(10*sizeof(int*));
    – fredo
    Jan 20, 2012 at 10:13

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