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what is decaying of array? is there any relation to the array pointers?

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In what context? –  Joren Sep 22 '09 at 17:27
Can you add a reference to where you saw the phrase, to add some context? –  daveb Sep 22 '09 at 17:28
little known: The unary plus operator can be used as an "decay operator": Given int a[10]; int b(void);, then +a is an int pointer and +b is a function pointer. Useful if you want to pass it to a template accepting a reference. –  Johannes Schaub - litb Sep 22 '09 at 18:36
@litb - parens would do the same (e.g., (a) should be an expression that evaluates to a pointer), right?. –  Michael Burr Sep 22 '09 at 19:30
Nono, that won't do it :) This "decay operator" goodness only works in C++. Unlike in C, arrays won't be unconditionally converted to pointers but only on need. You may also use it if you pass a static const class member that hasn't got a definition to a function taking a const reference: f(+string::npos);, and it won't require a definition. This one operator is very versatile, of course! :) –  Johannes Schaub - litb Sep 22 '09 at 20:07

7 Answers 7

up vote 69 down vote accepted

It's said that arrays "decay" into pointers. A C++ array declared as int numbers [5] cannot be re-pointed, i.e. you can't say numbers = 0x5a5aff23. More importantly the term decay signifies loss of type and dimension; numbers decay into int* by losing the dimension information (count 5) and the type is not int [5] any more. Look here for cases where the decay doesn't happen.

When you pass an array to a function directly it has decayed functionality, in that you lose the ability to call sizeof() on that item, because it essentially becomes a pointer. This is why it's preferred to pass by reference (among other reasons) or by pointer.

Three ways to pass in an array1:

void by_value(const T* array)   // const T array[] means the same
void by_pointer(const T (*array)[U])
void by_reference(const T (&array)[U])

The last two will give proper sizeof info, while the first one won't since the array argument has decayed to be assigned to the parameter.

1 The constant U should be known at compile-time.

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Phoebus, especially in C ;-) –  Michael Krelin - hacker Sep 22 '09 at 17:29
How is the first passing by value? –  rlbond Sep 22 '09 at 18:54
by_value is passing a pointer to the first element of the array; in the context of function parameters, T a[] is identical to T *a. by_pointer is passing the same thing, except the pointer value is now qualified const. If you want to pass a pointer to the array (as opposed to a pointer to the first element of the array), the syntax is T (*array)[U]. –  John Bode Sep 22 '09 at 19:35
"with an explicit pointer to that array" - this is incorrect. If a is an array of char, then a is of type char[N], and will decay to char*; but &a is of type char(*)[N], and will not decay. –  Pavel Minaev Sep 22 '09 at 19:39
oO the first and second declare the same function (the top-level const right before array is ignored). In C99, the toplevel const can also be specified for the first case - you can do void by_value(const T array[const]); - but this isn't significant in determining what function is declared. In any case, this answer probably should mention that void f(int array[N]); for any N > 0 is the same as void f(int *array);. –  Johannes Schaub - litb Sep 22 '09 at 19:41

Arrays are basically the same as pointers in C/C++, but not quite. Once you convert an array:

const int a[] = { 2, 3, 5, 7, 11 };

into a pointer (which works without casting, and can happen implicitly in some cases):

const int* p = a;

you lose the ability of the sizeof operator to count elements in the array:

assert( sizeof(p) != sizeof(a) );  // sizes are not equal

This lost ability is referred to as "decay".

For more details, check out this article about array decay.

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+1, just to make it explicit: the assertion will fail. (Actually, I think posting failing assert lines is a bad idea as it makes the article rather confusing -- asserts should never fail.) –  avakar Sep 22 '09 at 18:13
@avakar, thanks for the comment. I've updated the assert so that it does not fail. –  system PAUSE Sep 22 '09 at 18:35
Arrays are not basically the same as pointers; they are completely different animals. In most contexts, an array can be treated as though it were a pointer, and a pointer can be treated as though it were an array, but that's as close as they get. –  John Bode Sep 22 '09 at 19:39
@John, please pardon my imprecise language. I was trying to get to the answer without getting bogged down in a lengthy backstory, and "basically...but not quite" is as good an explanation as I ever got in college. I'm sure anyone who's interested can get a more accurate picture from your upvoted comment. –  system PAUSE Sep 23 '09 at 15:17

Here's what the standard says (C99 - Other operands - Lvalues, arrays, and function designators):

Except when it is the operand of the sizeof operator or the unary & operator, or is a string literal used to initialize an array, an expression that has type ‘‘array of type’’ is converted to an expression with type ‘‘pointer to type’’ that points to the initial element of the array object and is not an lvalue.

This means that pretty much anytime the array name is used in an expression, it is automatically converted to a pointer to the 1st item in the array.

Note that function names act in a similar way, but function pointers are used far less and in a much more specialized way that it doesn't cause nearly as much confusion as the automatic conversion of array names to pointers.

The C++ standard (4.2 Array-to-pointer conversion) loosens the conversion requirement to (emphasis mine):

An lvalue or rvalue of type “array of N T” or “array of unknown bound of T” can be converted to an rvalue of type “pointer to T.”

So the conversion doesn't have to happen like it pretty much always does in C (this lets functions overload or templates match on the array type).

This is also why in C you should avoid using array parameters in function prototypes/definitions (in my opinion - I'm not sure if there's any general agreement). They cause confusion and are a fiction anyway - use pointer parameters and the confusion might not go away entirely, but at least the parameter declaration isn't lying.

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What is an example line of code where an "expression that has type 'array of type'" is "a string literal used to initialize an array"? –  Garrett Jul 8 at 2:45
+1 I cannot understand why this isn't up-ticked more. It is not only accurate, cites the standard, and summarily helpful, it even goes to respectable lengths to use the word "decay" as frequently as the C standard does; i.e. not-at-all. –  WhozCraig Aug 15 at 0:56

It's when array rots and is being pointed at ;-)

Actually, it's just that if you want to pass an array somewhere, but the pointer is passed instead (because who the hell would pass the whole array for you), people say that poor array decayed to pointer.

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Nicely said. What would be a nice array that does not decay to a pointer or one that is prevented from decaying? Can you cite an example in C? Thanks. –  Unheilig Jan 10 at 5:20
@Unheilig, sure, one can vacuum-pack an array into struct and pass the struct. –  Michael Krelin - hacker Jan 10 at 9:13
It sure sounds like a nice and easy way to guarantee freshness, I wondered why no-one has mentioned this. And if you had to do this, would you declare the array as the first member within the struct or it doesn't matter? Ah, one more question, please don't mind: usually when a pointer points to the location one past the last element of the array, it's allowed, if we vacuum-pack the array within the structure in which there might be other member variables after the array, does this trick (pointing to location one past the last element of the array) still hold / work? +1, thanks. –  Unheilig Jan 10 at 15:38
I'm not sure what do you mean by "work". It's not allowed to access past the array, though it works as expected if you expect what is really to happen. That behaviour (though, again, officially undefined) is preserved. –  Michael Krelin - hacker Jan 10 at 20:08

"Decay" refers to the implicit conversion of an expression from an array type to a pointer type. In most contexts, when the compiler sees an array expression it converts the type of the expression from "N-element array of T" to "pointer to T" and sets the value of the expression to the address of the first element of the array. The exceptions to this rule are when an array is an operand of either the sizeof or & operators, or the array is a string literal being used as an initializer in a declaration.

Assume the following code:

char a[80];
strcpy(a, "This is a test");

The expression a is of type "80-element array of char" and the expression "This is a test" is of type "16-element array of char" (in C; in C++ string literals are arrays of const char). However, in the call to strcpy(), neither expression is an operand of sizeof or &, so their types are implicitly converted to "pointer to char", and their values are set to the address of the first element in each. What strcpy() receives are not arrays, but pointers, as seen in its prototype:

char *strcpy(char *dest, const char *src);

This is not the same thing as an array pointer. For example:

char a[80];
char *ptr_to_first_element = a;
char (*ptr_to_array)[80] = &a;

Both ptr_to_first_element and ptr_to_array have the same value; the base address of a. However, they are different types and are treated differently, as shown below:

a[i] == ptr_to_first_element[i] == (*ptr_to_array)[i] != *ptr_to_array[i] != ptr_to_array[i]

Remember that the expression a[i] is interpreted as *(a+i) (which only works if the array type is converted to a pointer type), so both a[i] and ptr_to_first_element[i] work the same. The expression (*ptr_to_array)[i] is interpreted as *(*a+i). The expressions *ptr_to_array[i] and ptr_to_array[i] may lead to compiler warnings or errors depending on the context; they'll definitely do the wrong thing if you're expecting them to evaluate to a[i].

sizeof a == sizeof *ptr_to_array == 80

Again, when an array is an operand of sizeof, it's not converted to a pointer type.

sizeof *ptr_to_first_element == sizeof (char) == 1
sizeof ptr_to_first_element == sizeof (char *) == whatever the pointer size
                                                  is on your platform

ptr_to_first_element is a simple pointer to char.

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+1 for explaining the expression interpretation for (*pointer_to_array)[i]. –  legends2k Oct 15 '13 at 23:41
Isn't "This is a test" is of type "16-element array of char" a "15-element array of char"? (length 14 + 1 for \0) –  chux Dec 7 '13 at 17:47

Arrays, in C, have no value.

Wherever the value of an object is expected but the object is an array, the address of its first element is used instead, with type pointer to (type of array elements).

In a function, all parameters are passed by value (arrays are no exception). When you pass an array in a function it "decays into a pointer" (sic); when you compare an array to something else, again it "decays into a pointer" (sic); ...

void foo(int arr[]);

Function foo expects the value of an array. But, in C, arrays have no value! So foo gets instead the address of the first element of the array.

int arr[5];
int *ip = &(arr[1]);
if (arr == ip) { /* something; */ }

In the comparison above, arr has no value, so it becomes a pointer. It becomes a pointer to int. That pointer can be compared with the variable ip.

In the array indexing syntax you are used to seeing, again, the arr is 'decayed to a pointer'

/* same as *(arr + 42); */
/* same as *(&(arr[0]) + 42); */

The only times an array doesn't decay into a pointer are when it is the operand of the sizeof operator, or the & operator (the 'address of' operator), or as a string literal used to initialize a character array.

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"Arrays have no value" - what's that supposed to mean? Of course arrays have value... they're objects, you can have pointers, and, in C++, references to them, etc. –  Pavel Minaev Sep 22 '09 at 19:40
I believe, strictly, "Value" is defined in C as the interpretation of an object's bits according to a type. I have a hard time figuring out a useful meaning of that with an array type. Instead, you can say that you convert to a pointer, but that's not interpreting the array's contents, it just gets its location. What you get is the value of a pointer (and it's an address), not the value of an array (this would be "the sequence of values of the contained items", as used in the definition of "string"). That said, i think it's fair to say "value of array" when one means the pointer one gets. –  Johannes Schaub - litb Sep 22 '09 at 19:56
I like to think of objects as the triplet [location, type, value] or the pair [location, data] where data is the pair [type, value]. For arrays the triplet is [location, type, location]. When an object is used as an operand for sizeof only the [type] matters; when it's used as an operand of the & operator only the [location] matters. I like the catchy phrase "Arrays have no value" because it's easy to remember and it reflects array usage in C. –  pmg Sep 22 '09 at 20:52
+1 for the phrase with a small fix; for arrays it's not even a triplet just a couplet [location, type]. Did you have something else in mind for the third location in array's case? I can't think of any. –  legends2k Jul 8 at 14:50
@legends2k: I think I used the third location in arrays to avoid making them a special case of only having a couplet. Maybe [location, type, void] would have been better. –  pmg Jul 8 at 15:55

Array decaying means that, when an array is passed as a parameter to a function, it's treated identically to ("decays to") a pointer.

void do_something(int *array) {
  // We don't know how big array is here, because it's decayed to a pointer.
  printf("%i\n", sizeof(array));  // always prints 4 on a 32-bit machine

int main (int argc, char **argv) {
    int a[10];
    int b[20];
    int *c;
    printf("%i\n", sizeof(a)); //prints 40 on a 32-bit machine
    printf("%i\n", sizeof(b)); //prints 80 on a 32-bit machine
    printf("%i\n", sizeof(c)); //prints 4 on a 32-bit machine

There are two complications or exceptions to the above.

First, when dealing with multidimensional arrays in C and C++, only the first dimension is lost. This is because arrays are layed out contiguously in memory, so the compiler must know all but the first dimension to be able to calculate offsets into that block of memory.

void do_something(int array[][10])
	// We don't know how big the first dimension is.

int main(int argc, char *argv[]) {
	int a[5][10];
	int b[20][10];
	return 0;

Second, in C++, you can use templates to deduce the size of arrays. Microsoft uses this for the C++ versions of Secure CRT functions like strcpy_s, and you can use a similar trick to reliably get the number of elements in an array.

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protected by Marco A. Nov 4 at 15:08

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