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You can see what I mean when you take "str" or &"str"[0] and &"str" and get identical pointers but different types.

Note: I'm on a system where string literals are not distinct.

printf("%p\n", "str");
printf("%p\n", &"str"[0]);
printf("%p\n", &"str");

// hypothetical output:
// 0xADD12E550  (ptr to char)
// 0xADD12E550  (ptr to char)
// 0xADD12E550  (ptr to arr of char)

So in theory, when I dereference &"str", I should be able to get the first character of the string since I am dereferencing the same pointer. Peculiarly, that's not the case, I have to dereference twice. Once to get the array, then again to get the first character constant:

// &"str" = 0xADD12E550
// *(0xADD12E550) = 0xADD12E550
// *(0xADD12E550) = 's'

// **(&"str") == 's'

Maybe then this question can also answer how this is possible:

#include <stdio.h>

void dafunk() {
  printf("dadftendirekt\n");
}

main() {
  void (*dafunkptr)() = dafunk;
  (***************dafunkptr)();

  return 0;
}
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4  
I honestly think the best answer to this question is: "If you do silly things, you get silly results. If you only do sensible things, you will only get sensible results." –  David Schwartz Apr 8 '12 at 23:45
    
There are no pointers. Printf() only sees a "pointer expression" (which also has a type attached to it) –  wildplasser Apr 8 '12 at 23:45
    
The second part of your question is a duplicate of this question. –  dasblinkenlight Apr 8 '12 at 23:46
    
@wildplasser: When you say "There are no pointer", do you mean that there are no pointer objects? The word "pointer" by itself is ambiguous; we have pointer types, pointer objects, pointer expressions, and pointer values. The C standard uses the unqualified word "pointer" to refer to pointer values; see, for example, the description of the malloc function, which returns "either a null pointer or a pointer to the allocated space". –  Keith Thompson Apr 9 '12 at 1:11
    
Of course there are pointer thingies. I intended to say that most people are thinking in terms of objects, while function arguments should be viewed as expressions (which of course inherit all their properties from the objects and constants that are part of them). The main syntactic element of C is an expression. Even an lvalue is an expression (not a thing). (I know you know, but most people think in terms of variables and assignments, not in terms of expressions and terms, etc) –  wildplasser Apr 9 '12 at 1:22

2 Answers 2

The object "str" is of type array 4 of char.

The value of "str" is of type pointer to char.

The value of &"str"[0] is of type pointer to char.

The value of &"str" is of type pointer to an array 4 of char.

EDIT:

So now to access for example the first character of the string, from "str" you have to dereference the expression once:

char s = *"str";  // or s = "str"[0] 

or from the expression &"str" you have to dereference the expression twice as its type is a pointer to an array:

char s = **&"str";   // or s = *(&"str")[0]
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I already established that on the question. –  Espresso Apr 9 '12 at 0:02
    
@Espresso in that case I cannot clearly see what is your question –  ouah Apr 9 '12 at 0:05
    
Please see my comment on Jonathan's answer. Sorry, I'm on a mobile device. –  Espresso Apr 9 '12 at 0:09
    
@Espresso see my edit –  ouah Apr 9 '12 at 0:17
    
You make me LULz. When I dereference say, 0x123456789 which is a pointer to some integer. Shouldn't I always get the value that's it's pointing to? But that's not the case in my example. How did the pointer change types under my feet? How was I able to dereference it twice and get different values? –  Espresso Apr 9 '12 at 0:25

The expression "str" is of type char[4]. (In C++, it would be const char[4].)

Any expression of array type is, in most contexts, implicitly converted to a pointer to the first element of the array object. This conversion is commonly referred to as "decaying". The exceptions to this are:

  • When it's the operand of the unary sizeof operator (sizeof "str" yields the size of the array, not the size of a pointer).
  • When it's the operand of the unary & operator (&"str" yields a result of type char(*)[4], not char*).
  • When it's a string literal in an initializer used to initialize an array object (not applicable here).

In these three cases, an array expression keeps its array type.

A string literal refers to an implicitly created array object with static storage duration, big enough to hold the characters of the literal plus the terminating '\0' null character. In this case, "str" refers to an anonymous static object of type char[4].

So:

printf("%p\n", "str");

"str" is implicitly converted to a char* value, pointing to the 's' of "str".

printf("%p\n", &"str"[0]);

The "str" in "str"[0] decays to char*, as above. "str"[0" yields a char* value, pointing to the 's'. So "str" and "str"[0] are of the same type and value.

printf("%p\n", &"str");

Here, since "str" is the operand of &, the decay doesn't occur, so &"str" yields the address of the anonymous char[4] object, not the address of its first character. This expression is of type char(*)[4], or "pointer to array of 4 char".

The expressions &"str"[0] and &"str" both yield pointer values, both of which point to the same location in memory, but they're of different types.

In all three cases, the result of evaluating the expression is passed as an argument to printf. printf with a "%p" format requires an argument of type void*. In the first two cases, you're passing a char*, and the language's requirements for char* and void* imply that it will work as expected. In the third case, there are no such rules for char* vs. char(*)[4], so the behavior of

printf("%p\n", &"str");

is undefined.

As it happens, in most implementations all pointer types have the same size and representation, so you can get away with passing a pointer of any arbitrary type to printf with "%p".

In all three cases, you could (and probably should) explicitly cast the expression to void*, avoiding the undefined behavior:

printf("%p\n", (void*)"str");
printf("%p\n", (void*)&"str"[0]);
printf("%p\n", (void*)&"str");

The second part of your question deals with a distinct issue; it's about pointers to functions. The rules for expressions of pointer type are similar to those of array type: an expression of function type (such as a function name) is implicitly converted to a pointer to the function, except when it's the operand of sizeof (which is illegal) or & (which yields the address of the function). That's why applying * or & to a function acts like a no-op. In *func, func first decays to a pointer to the function, * dereferences the pointer, and the result again decays to a pointer to the function. In &func, the & inhibits the decay, but it yields the same pointer to the function that func by itself would yield.

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Memory addresses have types right? Depending on what the pointer (memory address) is pointing to it can be int *, char *, … Is that right? –  Espresso Apr 9 '12 at 1:42
    
@Espresso: Yes, any C pointer (object|expression|value) has some particular type. Two pointers of different type can nevertheless point to the same memory location. You can detect that by converting them to a common type like void* and comparing them with ==. –  Keith Thompson Apr 9 '12 at 2:03
1  
@Espresso: There's no implicit cast involved. A string literal is of type array of char, in this case, char[4]. Applying the address operator simply yields the address of that array. What seems odd about it is that the array expression isn't implicitly converted to a pointer, because it's the operand of the &. –  Keith Thompson Apr 9 '12 at 4:16
    
OK. Your answer didn't directly answer my question. But I found out. For some reason, when I use the address operator on a string literal, the C compiler implicitly casted the pointer that the string literal decayed into to a pointer to an array of characters. That's my evaluation, correct me if I'm wrong. I really don't know what's going on under the hood. I don't know assembly like the other guy implied. If my evaluation turns out to be true, why C would cast instead of giving me a different pointer is another question. –  Espresso Apr 9 '12 at 4:18
    
@Espresso: You understand that arrays and pointers are two different things, yes? –  GManNickG Apr 9 '12 at 4:22

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