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people.

I'm trying to grasp the differences between these three declarations:

char p[5];
char *p[5];
char (*p)[5];

I'm trying to find this out by doing some tests, because every guide of reading declarations and stuff like that has not helped me so far. I wrote this little program and it's not working (I've tried other kinds of use of the third declaration and I've ran out of options):

#include <stdio.h>                                                              
#include <string.h>                                                             
#include <stdlib.h>                                                             

int main(void) {                                                                
        char p1[5];                                                             
        char *p2[5];                                                            
        char (*p3)[5];                                                          

        strcpy(p1, "dead");                                                     

        p2[0] = (char *) malloc(5 * sizeof(char));                              
        strcpy(p2[0], "beef");                                                  

        p3[0] = (char *) malloc(5 * sizeof(char));                              
        strcpy(p3[0], "char");                                                  

        printf("p1 = %s\np2[0] = %s\np3[0] = %s\n", p1, p2[0], p3[0]);          

        return 0;                                                               
}

The first and second works alright, and I've understood what they do. What is the meaning of the third declaration and the correct way to use it?

Thank you!

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Decoding declarations is my least favorite part of C and C++. –  Mark Ransom Jun 24 '11 at 15:06

4 Answers 4

up vote 12 down vote accepted

The third is a pointer to an array of 5 chars, whereas the second is an array of 5 pointers to char.

Imagine it like this:

________          _____________________
|0x7777| -------> | H | e | l | l | o |
|______|          |_0_|_1_|_2_|_3_|_4_|
    p             ^
                  |
                  0x7777  

Whereas the second one looks like that:

   "abc"  "def"  "ghi"  "jkl"  "mno"
    ^      ^      ^      ^      ^
    |      |      |      |      |
____________________________________
|0x9999|0x7777|0x3333|0x2222|0x6666|
|___0__|___1__|___2__|___3__|___4__|
                  p

This is one of the cases where understanding the difference between pointers and arrays is crucial. An array is an object whose size is the size of each of its elements times the count, whereas a pointer is merely an address.

In the second case, sizeof(p) will yield 5 * the_size_of_a_pointer.

In the third case, sizeof(p) will yield the_size_of_a_pointer, which is usually 4 or 8, depending on the target machine.

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9  
The clockwise spiral rule is a handy thing to know when you're messing with C. –  Noufal Ibrahim Jun 24 '11 at 12:18
    
I tried to use p3 allocating 5 chars and pointing p3 to those and it didn't work. It's not working like you said... Would you mind posting some example code or something clearer? –  jpmelos Jun 24 '11 at 12:21
    
In the third case, sizeof(p3) is not yielding what you said, it's yielding 8, which is the size of a pointer in my machine. –  jpmelos Jun 24 '11 at 12:41
    
@jpmelos: The third doesn't work because p3 is an unitialised pointer and you are attempting to dereference it with the array subscript operator (p3[0]). You could do something like that: p3 = &p1. –  Blagovest Buyukliev Jun 24 '11 at 12:45
    
@jpmelos: oops, yes, a typing mistake. –  Blagovest Buyukliev Jun 24 '11 at 12:46

It's a pointer to an array of chars. It is explained in the C FAQ. In the future, when you don't understand a declaration, use cdecl or cdecl(1).

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Thank you very much, your link to the C FAQ helped me greatly understanding this topic. –  jpmelos Jun 24 '11 at 13:05
char p[5];      // p is a 5-element array of char
char *p[5];     // p is a 5-element array of pointer to char
char (*p)[5];   // p is a pointer to a 5-element array of char

C declaration syntax is built around the types of expressions, not objects. The idea is that the form of the declaration matches the form of the expression as it would appear in the code.

In the cases above, we're dealing with arrays. In the first case, p is an array of char; to access a particular character value, we would simply index into the array:

val = p[i];

The type of the expression p[i] is char, thus the declaration of p is char p[5].

In the next case, p is an array of pointers to char; to access the value, we index into the array and dereference the result:

val = *p[i];

Postfix operators like [] have a higher precedence than unary operators like *, so the above is parsed as

val = *(p[i]);

The type of the expression *p[i] is char, thus the declaration of p is char *p[5].

In the final case, p is a pointer to an array of char, so to access a char value we have to dereference the array pointer and then subscript into the result:

val = (*p)[i];

Because [] has higher precedence than unary *, we have to use parentheses to explicitly group * with p (as opposed to p[i]). Again, the type of the expression (*p)[i] is char, so the declaration of p is char (*p)[5].

EDIT

Pointers to arrays show up in the following contexts:

  1. You're explicitly taking the address of an N-dimensional array:

    int x[10];
    int (*px)[10] = &x;
    
    Note that while the expressions x and &x yield the same value (the address of the first element of the array), they have different types (int * vs int (*)[10]).

  2. You're dynamically allocating an array-type object:

    int (*px)[10] = malloc(sizeof *px);
    

  3. An N-dimensional array expression "decays" into a pointer to an (N-1)-dimension array:

    int x[10][20];
    foo(x);
    ...
    void foo(int (*px)[20]){...}
    

share|improve this answer
    
+1. Very good explanation! Thank you, really made it clear how to think about declarations! –  jpmelos Jun 24 '11 at 15:46
    
In your edit, first context, you say x has type int * and &x has type int (*)[10]. You actually mean x has type int [10], I guess? –  jpmelos Jun 25 '11 at 22:58
1  
@jpmelos: Since it isn't an operand to sizeof or &, x would decay to int *. –  John Bode Jun 26 '11 at 19:51
    
Oh! I got it now! Thank you! –  jpmelos Jun 26 '11 at 20:02
char (*p3)[5];

actually declares a pointer to an array of 5 char. It means it should point to a pointer that points to an array of 5 char. It doesn't allocate 5 of anything, just a pointer, and it should point to something that points to 5 char.

So, the correct use is:

#include <stdio.h>                                                              
#include <string.h>                                                             
#include <stdlib.h>                                                             

int main(void) {                                                                
        char p1[5];                                                             
        char *p2[5];                                                            
        char (*p3)[5];                                                          

        strcpy(p1, "dead");                                                     

        p2[0] = (char *) malloc(5 * sizeof(char));                              
        strcpy(p2[0], "beef");                                                  

        p3 = &p1;                                                               

        printf("p1 = %s\np2[0] = %s\np3 = %s\n", p1, p2[0], *p3);               

        return 0;                                                               
}

If you want to access a single position of that p1 string using p3 to access it, you must do (*p3)[2], for example. It'll access the third position. That is because you first must transform p3 into p1 (the (*p3) dereferences before doing the position arithmetics) and then access the third position of that address (pointed by the dereferenced pointer).

share|improve this answer
    
Great, you summarised my answer better :-) –  Blagovest Buyukliev Jun 24 '11 at 13:04

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