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I'm a little bit confused about something. I was under the impression that the correct way of reading a C string with scanf() went along the lines of

(never mind the possible buffer overflow, it's just a simple example)

char string[256];
scanf( "%s" , string );

However, the following seems to work too,

scanf( "%s" , &string );

Is this just my compiler (gcc), pure luck, or something else?

  • In the second case, there's actually no possible buffer overflow, as you aren't using that buffer at all. Either that, or you could say that any string larger than 3 characters will overflow your "buffer". – T.E.D. Mar 23 '11 at 15:04
  • I was referring to the first example. Also, others have already pointed out what's going on here. – abeln Mar 23 '11 at 15:08
  • Yup. Tried it out, and Gareth is right. Weird. – T.E.D. Mar 23 '11 at 15:18
  • Since this question is returned by searches for "how to read a string with scanf", it might be appropriate to point out that this question is about ways to pass the pointer to the buffer to scanf, and both the question and the accepted answer focus on that, and omit the critically important restrictions for maximum input length that should be used in real code (but are besides the point for this question). – Arkku Sep 21 '18 at 12:10
129

An array "decays" into a pointer to its first element, so scanf("%s", string) is equivalent to scanf("%s", &string[0]). On the other hand, scanf("%s", &string) passes a pointer-to-char[256], but it points to the same place.

Then scanf, when processing the tail of its argument list, will try to pull out a char *. That's the Right Thing when you've passed in string or &string[0], but when you've passed in &string you're depending on something that the language standard doesn't guarantee, namely that the pointers &string and &string[0] -- pointers to objects of different types and sizes that start at the same place -- are represented the same way.

I don't believe I've ever encountered a system on which that doesn't work, and in practice you're probably safe. None the less, it's wrong, and it could fail on some platforms. (Hypothetical example: a "debugging" implementation that includes type information with every pointer. I think the C implementation on the Symbolics "Lisp Machines" did something like this.)

  • 5
    +1. It's also trivial to verify that array decay results in &string working the same as string (instead of resulting in random memory corruption, as other answers incorrectly assert): printf("%x\n%x\n", string, &string); – Josh Kelley Mar 23 '11 at 15:01
  • @Josh Kelley interesting, I would take it then that this would not be the case with a pointer to a string allocated through malloc()? – abeln Mar 23 '11 at 15:04
  • 4
    @abeln: Correct. For a string allocated through malloc(), string is a pointer, and &string is the address of that pointer, so the two are NOT interchangeable. As Gareth explains, even for the case of array decay, string and &string are technically not the same types (even though they happen to be interchangeable for most architectures), and gcc will give a warning for your second example if you turn on -Wall. – Josh Kelley Mar 23 '11 at 15:09
  • @Josh Kelley: thanks, I'm glad I could clear my mind on this. – abeln Mar 23 '11 at 15:12
  • 1
    @JCooper str, &str[0] both represent the same thing (the start of the array), and although not necessarily the &str is also the same memory address. Now strPtr points to str so the memory address stored inside of strPtr is the same as str and thats 12fe60. Finally &strPtr is the address of the variable strPtr, this is not the value stores in strptr but the actual memory address of strPtr. Since strptr is a different variable than all the others it also has a different memory address, in this case 12fe54 – Juan Besa May 22 '13 at 1:34
-7

I think that this below is accurate and it may help. Feel free to correct it if you find any errors. I'm new at C.

char str[]  
  1. array of values of type char, with its own address in memory
  2. array of values of type char, with its own address in memory as many consecutive addresses as elements in the array
  3. including termination null character '\0' &str, &str[0] and str, all three represent the same location in memory which is address of the first element of the array str

    char *strPtr = &str[0]; //declaration and initialization

alternatively, you can split this in two:

char *strPtr; strPtr = &str[0];
  1. strPtr is a pointer to a char
  2. strPtr points at array str
  3. strPtr is a variable with its own address in memory
  4. strPtr is a variable that stores value of address &str[0]
  5. strPtr own address in memory is different from the memory address that it stores (address of array in memory a.k.a &str[0])
  6. &strPtr represents the address of strPtr itself

I think that you could declare a pointer to a pointer as:

char **vPtr = &strPtr;  

declares and initializes with address of strPtr pointer

Alternatively you could split in two:

char **vPtr;
*vPtr = &strPtr
  1. *vPtr points at strPtr pointer
  2. *vPtr is a variable with its own address in memory
  3. *vPtr is a variable that stores value of address &strPtr
  4. final comment: you can not do str++, str address is a const, but you can do strPtr++

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