104

Wouldn't the pointer returned by the following function be inaccessible?

char *foo(int rc)
{
    switch (rc)
    {
        case 1:

            return("one");

        case 2:

            return("two");

        default:

            return("whatever");
    }
}

So the lifetime of a local variable in C/C++ is practically only within the function, right? Which means, after char* foo(int) terminates, the pointer it returns no longer means anything, right?

I'm a bit confused about the lifetime of a local variable. What is a good clarification?

10
  • 13
    The only "var" you have in your function is the parameter int rc. Its lifetime ends at each one of the return-s. The pointers you are returning are to string literals. String literals have static storage duration: their lifetime is at least as long as that of the program.
    – Kaz
    Apr 2, 2012 at 3:22
  • 14
    @PedroAlves Why not? Methods allow abstraction; what if in the future the string will be read from a translation resource, but internationalization support isn't needed for V1 (or V0.5) of a product?
    – dlev
    May 9, 2013 at 21:02
  • 1
    @PedroAlves "Your code will sure works (and you can see it if try to compile)," That does not follow. Many (most? Essentially every?) c compiler will consume illegal code, and often emit code that appears to work. But try it in another compiler (or even a different version of the same compiler) and it may fall over. May 9, 2013 at 21:51
  • 6
    @PedroAlves, a function that returns a single constant string might be of limited use, but how about one that returns any one of a number of constant strings depending on the input or object state? A simple example would be a function to convert an enumeration into its string representation. May 9, 2013 at 21:55
  • 5
    You've never seen the strerror function, evidently.
    – Kaz
    May 9, 2013 at 23:30

9 Answers 9

103

Yes, the lifetime of a local variable is within the scope({,}) in which it is created.

Local variables have automatic or local storage. Automatic because they are automatically destroyed once the scope within which they are created ends.

However, What you have here is a string literal, which is allocated in an implementation-defined read-only memory. String literals are different from local variables and they remain alive throughout the program lifetime. They have static duration [Ref 1] lifetime.

A word of caution!

However, note that any attempt to modify the contents of a string literal is an undefined behavior (UB). User programs are not allowed to modify the contents of a string literal.
Hence, it is always encouraged to use a const while declaring a string literal.

const char*p = "string"; 

instead of,

char*p = "string";    

In fact, in C++ it is deprecated to declare a string literal without the const though not in C. However, declaring a string literal with a const gives you the advantage that compilers would usually give you a warning in case you attempt to modify the string literal in the second case.

Sample program:

#include<string.h> 
int main() 
{ 
    char *str1 = "string Literal"; 
    const char *str2 = "string Literal"; 
    char source[]="Sample string"; 
 
    strcpy(str1,source);    // No warning or error just Undefined Behavior 
    strcpy(str2,source);    // Compiler issues a warning 
 
    return 0; 
} 

Output:

cc1: warnings being treated as errors
prog.c: In function ‘main’:
prog.c:9: error: passing argument 1 of ‘strcpy’ discards qualifiers from pointer target type

Notice the compiler warns for the second case, but not for the first.


To answer the question being asked by a couple of users here:

What is the deal with integral literals?

In other words, is the following code valid?

int *foo()
{
    return &(2);
} 

The answer is, no this code is not valid. It is ill-formed and will give a compiler error.

Something like:

prog.c:3: error: lvalue required as unary ‘&’ operand
     

String literals are l-values, i.e: You can take the address of a string literal, but cannot change its contents.
However, any other literals (int, float, char, etc.) are r-values (the C standard uses the term the value of an expression for these) and their address cannot be taken at all.


[Ref 1]C99 standard 6.4.5/5 "String Literals - Semantics":

In translation phase 7, a byte or code of value zero is appended to each multibyte character sequence that results from a string literal or literals. The multibyte character sequence is then used to initialize an array of static storage duration and length just sufficient to contain the sequence. For character string literals, the array elements have type char, and are initialized with the individual bytes of the multibyte character sequence; for wide string literals, the array elements have type wchar_t, and are initialized with the sequence of wide characters...

It is unspecified whether these arrays are distinct provided their elements have the appropriate values. If the program attempts to modify such an array, the behavior is undefined.

11
  • What if the user is returning some thing like this. char *a=&"abc"; return a; Will this not be valid?
    – Ashwin
    Apr 2, 2012 at 2:59
  • @Ashwin: The type of the string literal is char (*)[4]. This is because, type of "abc" is char[4] and pointer to an array of 4 characters is declared as char (*)[4], So If you need to take address of it, You need to do it as char (*a)[4] = &"abc"; and Yes, it is valid.
    – Alok Save
    Apr 2, 2012 at 3:10
  • @Als "abc" is char[4]. (Because of the '\0')
    – asaelr
    Apr 2, 2012 at 3:13
  • 1
    Maybe it would also be a good idea to warn that char const s[] = "text"; does not make s a character literal, and therefore s will be destroyed at the end of the scope, so any surviving pointers to it will dangle.
    – celtschk
    Apr 2, 2012 at 14:34
  • 2
    @celtschk: I would love to, but the Q is specifically about string literals So I would stick to the topic at hand.However, For ones interested my answer here, What is the difference between char a[] = “string” and char *p = “string”? should be rather helpful.
    – Alok Save
    Apr 2, 2012 at 14:56
81

It's valid. String literals have static storage duration, so the pointer is not dangling.

For C, that is mandated in section 6.4.5, paragraph 6:

In translation phase 7, a byte or code of value zero is appended to each multibyte character sequence that results from a string literal or literals. The multibyte character sequence is then used to initialize an array of static storage duration and length just sufficient to contain the sequence.

And for C++ in section 2.14.5, paragraphs 8-11:

8 Ordinary string literals and UTF-8 string literals are also referred to as narrow string literals. A narrow string literal has type “array of n const char”, where n is the size of the string as defined below, and has static storage duration (3.7).

9 A string literal that begins with u, such as u"asdf", is a char16_t string literal. A char16_t string literal has type “array of n const char16_t”, where n is the size of the string as defined below; it has static storage duration and is initialized with the given characters. A single c-char may produce more than one char16_t character in the form of surrogate pairs.

10 A string literal that begins with U, such as U"asdf", is a char32_t string literal. A char32_t string literal has type “array of n const char32_t”, where n is the size of the string as defined below; it has static storage duration and is initialized with the given characters.

11 A string literal that begins with L, such as L"asdf", is a wide string literal. A wide string literal has type “array of n const wchar_t”, where n is the size of the string as defined below; it has static storage duration and is initialized with the given characters.

1
14

String literals are valid for the whole program (and are not allocated not the stack), so it will be valid.

Also, string literals are read-only, so (for good style) maybe you should change foo to const char *foo(int)

5
  • What if the user is returning some thing like this. char *a=&"abc"; return a; Will this not be valid?
    – Ashwin
    Apr 2, 2012 at 2:59
  • &"abc" is not char*. it's an address of array, and its type is char(*)[4]. However, either return &"abc"; and char *a="abc";return a; are valid.
    – asaelr
    Apr 2, 2012 at 3:03
  • @asaelr: Actually, it is more than just for sake of for a good style, check my answer for the details.
    – Alok Save
    Apr 2, 2012 at 3:16
  • @Als Well, if he writes the whole program, he can avoid changing the string without writing const, and it will be completely legal, but it still bad style.
    – asaelr
    Apr 2, 2012 at 3:18
  • if it's valid for the whole program, why we need to malloc it?
    – TomSawyer
    Jun 18, 2020 at 19:27
8

Yes, it is valid code, see case 1 below. You can safely return C strings from a function in at least these ways:

  • const char* to a string literal. It can't be modified and must not be freed by caller. It is rarely useful for the purpose of returning a default value, because of the freeing problem described below. It might make sense if you actually need to pass a function pointer somewhere, so you need a function returning a string..

  • char* or const char* to a static char buffer. It must not be freed by the caller. It can be modified (either by the caller if not const, or by the function returning it), but a function returning this can't (easily) have multiple buffers, so it is not (easily) threadsafe, and the caller may need to copy the returned value before calling the function again.

  • char* to a buffer allocated with malloc. It can be modified, but it must usually be explicitly freed by the caller and has the heap allocation overhead. strdup is of this type.

  • const char* or char* to a buffer, which was passed as an argument to the function (the returned pointer does not need to point to the first element of argument buffer). It leaves responsibility of buffer/memory management to the caller. Many standard string functions are of this type.

One problem is, mixing these in one function can get complicated. The caller needs to know how it should handle the returned pointer, how long it is valid, and if caller should free it, and there's no (nice) way of determining that at runtime. So you can't, for example, have a function, which sometimes returns a pointer to a heap-allocated buffer which caller needs to free, and sometimes a pointer to a default value from string literal, which caller must not free.

1
6

Good question. In general, you would be right, but your example is the exception. The compiler statically allocates global memory for a string literal. Therefore, the address returned by your function is valid.

That this is so is a rather convenient feature of C, isn't it? It allows a function to return a precomposed message without forcing the programmer to worry about the memory in which the message is stored.

See also @asaelr's correct observation re const.

2
  • :What if the user is returning some thing like this. char *a=&"abc"; return a; Will this not be valid?
    – Ashwin
    Apr 2, 2012 at 2:59
  • Right. Actually, one can just write const char *a = "abc";, omitting the &. The reason is that a double-quoted string resolves to the address of its initial character.
    – thb
    Apr 2, 2012 at 3:02
3

Local variables are only valid within the scope they're declared, however you don't declare any local variables in that function.

It's perfectly valid to return a pointer to a string literal from a function, as a string literal exists throughout the entire execution of the program, just as a static or a global variable would.

If you're worrying about what you're doing might be invalid undefined, you should turn up your compiler warnings to see if there is in fact anything you're doing wrong.

2
  • What if the user is returning some thing like this. char *a=&"abc"; return a; Will this not be valid?
    – Ashwin
    Apr 2, 2012 at 3:00
  • @Ashwin: &"abc" isn't of type char*, however both "abc" and &"abc" are valid throughout the whole execution of the program.
    – AusCBloke
    Apr 2, 2012 at 3:05
2

str will never be a dangling pointer, because it points to a static address where string literals resides.

It will be mostly read-only and global to the program when it will be loaded.

Even if you try to free or modify, it will throw a segmentation fault on platforms with memory protection.

2
0

A local variable is allocated on the stack. After the function finishes, the variable goes out of scope and is no longer accessible in the code. However, if you have a global (or simply - not yet out of scope) pointer that you assigned to point to that variable, it will point to the place in the stack where that variable was. It could be a value used by another function, or a meaningless value.

1
  • What if the user is returning some thing like this. char *a=&"abc"; return a; Will this not be valid?
    – Ashwin
    Apr 2, 2012 at 3:00
-1

In the above example shown by you, you are actually returning the allocated pointers to whatever function that calls the above. So it would not become a local pointer. And moreover, for the pointers that are needed to be returned, memory is allocated in the global segment.

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