What's the difference between

char* name

which points to a constant string literal, and

const char* name
  • what do you mean by "constant string literal" in C (not C++) – gbulmer Mar 23 '12 at 4:49
  • 1
    ... char *name can be made to point to a constant string literal – Iceman Mar 23 '12 at 15:15
  • the constant in "constant string literal" is redundant, since all string literals are in theory constant entities. It's the contents of the variable that can be made either constant or mutable. The "const" declaration simply will throw a compile time error if you try to change the contents of the character pointed to by "name" – Ngineer Jul 31 '16 at 4:49
  • Simple: "char *name" name is a pointer to char, i.e. both can be change here. "const char *name" name is a pointer to const char i.e. pointer can change but not char. – akD Apr 27 '17 at 6:20
up vote 321 down vote accepted

char* is a mutable pointer to a mutable character/string.

const char* is a mutable pointer to an immutable character/string. You cannot change the contents of the location(s) this pointer points to. Also, compilers are required to give error messages when you try to do so. For the same reason, conversion from const char * to char* is deprecated.

char* const is an immutable pointer (it cannot point to any other location) but the contents of location at which it points are mutable.

const char* const is an immutable pointer to an immutable character/string.

  • 3
    Confusion can get cleared up with the use of a variable after the statements mentioned above and by giving reference to that variable. – ankit.karwasra Oct 8 '13 at 9:16
  • 7
    Wow, there is const char* const, cool! – Pei Mar 21 '15 at 14:56
  • 1
    @ankit.karwasra, You missed out one more: char const * – Pacerier May 13 '15 at 3:27
  • I supose two options with mutable character/string are highly dangerous, since you could do a segmetation fault memory, and if you are really smart you could hack the computer. That is why compilers always shown warnings in those implementations I think – Daniel N. May 15 '15 at 4:22
  • Won't mutating char * give segmentation fault while running? – Divyanshu Maithani Feb 21 '17 at 8:52
char *name

You can change the char to which name points, and also the char at which it points.

const char* name

You can change the char to which name points, but you cannot modify the char at which it points.
correction: You can change the pointer, but not the char to which name points to (https://msdn.microsoft.com/en-us/library/vstudio/whkd4k6a(v=vs.100).aspx, see "Examples"). In this case, the const specifier applies to char, not the asterisk.

According to the MSDN page and http://en.cppreference.com/w/cpp/language/declarations, the const before the * is part of the decl-specifier sequence, while the const after * is part of the declarator.
A declaration specifier sequence can be followed by multiple declarators, which is why const char * c1, c2 declares c1 as const char * and c2 as const char.

EDIT:

From the comments, your question seems to be asking about the difference between the two declarations when the pointer points to a string literal.

In that case, you should not modify the char to which name points, as it could result in Undefined Behavior. String literals may be allocated in read only memory regions (implementation defined) and an user program should not modify it in anyway. Any attempt to do so results in Undefined Behavior.

So the only difference in that case (of usage with string literals) is that the second declaration gives you a slight advantage. Compilers will usually give you a warning in case you attempt to modify the string literal in the second case.

Online Sample Example:

#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.

  • Thanks.. i was mixing with the constant string literal, which is defined as: char* name = "String Literal"; Changing "String Literal" is undefined.. – Iceman Mar 23 '12 at 4:20
  • @user1279782: Err, Wait! Are you talking about pointes pointing to string literals here? In that case You should not modify the char to which the name points in either case.It could result in UB. – Alok Save Mar 23 '12 at 4:24
  • Yes, that was the point. So in that case char* name and const char* name behave similar, right? – Iceman Mar 23 '12 at 4:28
  • 4
    This answer is either extremely ambiguous or just plain wrong. I would interpret "You cannot change the char to which name points, but You can modify the char at which it points." As not being able to modify the pointer itself, but being able to modify the memory location that it points to, which is incorrect: ideone.com/6lUY9s alternatively for pure C: ideone.com/x3PcTP – shroudednight Jan 4 '13 at 23:34
  • 1
    @shroudednight: You need to learn a little more about Undefined behaviors, and need to distinguish between: allowed and should not be done. :) – Alok Save Jan 5 '13 at 5:29
char mystring[101] = "My sample string";
const char * constcharp = mystring; // (1)
char const * charconstp = mystring; // (2) the same as (1)
char * const charpconst = mystring; // (3)

constcharp++; // ok
charconstp++; // ok
charpconst++; // compile error

constcharp[3] = '\0'; // compile error
charconstp[3] = '\0'; // compile error
charpconst[3] = '\0'; // ok

// String literals
char * lcharp = "My string literal";
const char * lconstcharp = "My string literal";

lcharp[0] = 'X';      // Segmentation fault (crash) during run-time
lconstcharp[0] = 'X'; // compile error

// *not* a string literal
const char astr[101] = "My mutable string";
astr[0] = 'X';          // compile error
((char*)astr)[0] = 'X'; // ok
  • 1
    None of your pointers point to "constant string literals" as per the question. – caf Mar 23 '12 at 4:25
  • It's worth noting that changing the char * value gives segmentation fault since we are trying to modify a string literal (which is present in read only memory) – Divyanshu Maithani Feb 21 '17 at 8:50

In neither case can you modify a string literal, regardless of whether the pointer to that string literal is declared as char * or const char *.

However, the difference is that if the pointer is const char * then the compiler must give a diagnostic if you attempt to modify the pointed-to value, but if the pointer is char * then it does not.

  • 1
    "In neither case can you modify a string literal, regardless of whether ... [it] is declared as char * or const char *" I agree that the programmer should not try, but are you saying that every C compiler, on every platform will reject the code, arrange for the code to fail at run time, or something else? I believe, one file could have the definition and initialisation, and another file might contain extern ... name and have *name = 'X';. On 'proper operating system', that might fail, but on embedded systems, I'd expect it to do something platform/compiler specific. – gbulmer Mar 23 '12 at 4:44
  • @gbulmer: You cannot modify a string literal in a correct C program. What an incorrect C program which tries may result in is neither here nor there. – caf Mar 23 '12 at 5:27
  • caf - what is the definition of a correct C program? – gbulmer Mar 23 '12 at 11:16
  • @gbulmer: One useful definition is a program that doesn't break any constraints specified by the C language standard. In other words, a program that modifies a string literal is incorrect in the same way as one that dereferences a null pointer or performs a division by 0 is incorrect. – caf Mar 23 '12 at 14:26
  • 1
    When a standard can't assert anything either way, I think defining behaviour as being 'undefined' seems to be exactly the right boundary and helpful. To assert the relation a 'correct C program' 'cannot dereference a null pointer' sounds equivalent to proving the halting problem. But I don't mind. I wouldn't do it and expect to get away with it 'scott free' :-) – gbulmer Mar 24 '12 at 1:15

The first you can actually change if you want to, the second you can't. Read up about const correctness (there's some nice guides about the difference). There is also char const * name where you can't repoint it.

  • What exactly can change? – Antti Haapala Aug 24 '17 at 18:49

Actually, char* name is not a pointer to a constant, but a pointer to a variable. You might be talking about this other question.

What is the difference between char * const and const char *?

The question is what's the difference between

char *name

which points to a constant string literal, and

const char *cname

I.e. given

char *name = "foo";

and

const char *cname = "foo";

There is not much difference between the 2 and both can be seen as correct. Due to the long legacy of C code, the string literals have had a type of char[], not const char[], and there are lots of older code that likewise accept char * instead of const char *, even when they do not modify the arguments.

The principal difference of the 2 in general is that *cname or cname[n] will evaluate to lvalues of type const char, whereas *name or name[n] will evaluate to lvalues of type char, which are modifiable lvalues. A conforming compiler is required to produce a diagnostics message if target of the assignment is not a modifiable lvalue; it need not produce any warning on assignment to lvalues of type char:

name[0] = 'x'; // no diagnostics *needed*
cname[0] = 'x'; // a conforming compiler *must* produce a diagnostics message

The compiler is not required to stop the compilation in either case; it is enough that it produces a warning for the assignment to cname[0]. The resulting program is not a correct program. The behaviour of the construct is undefined. It may crash, or even worse, it might not crash, and might change the string literal in memory.

CASE 1:

char *str = "Hello";
str[0] = 'M'  //No warning or error, just Undefined Behavior

The above sets str to point to the literal value "Hello" which is hard-coded in the program's binary image, which is flagged as read-only in memory, means any change in this String literal is illegal and that would throw segmentation faults.

CASE 2:

const char *str = "Hello";
str[0] = 'M'  //Compiler issues a warning

CASE 3:

char str[] = "Hello";
str[0] = 'M'; // legal and change the str = "Mello".

Just to give an extra example:

    std::cout << typeid(2.3).name() << '\n'; // -----> prints "double" simply because
    //2.3 is a double
    //But the "double" returned by typeid(2.3).name() is indeed a 
    //const char * which consists of 'd','o','u','b','l','e'and'\0'.
    //Here's a simple proof to this:
    std::cout << typeid(typeid(2.3).name()).name() << '\n'; //prints: "const char *"
    const char* charptr
    charptr = typeid(2.3).name();
    std::cout << charptr[3]; // --------->  prints: "b"

(I'm using the typeinfo library: http://www.cplusplus.com/reference/typeinfo/type_info/name)

    //Now let's do something more interesting:
    char* charptr2="hubble";
    strcpy(charptr, charptr2);  // --------> Oops! Sorry, this is not valid!

You can run it and see things better for yourself.

  • the question is about C, yet you answer with C++ code. – Antti Haapala Aug 24 '17 at 18:48

Your Answer

By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

Not the answer you're looking for? Browse other questions tagged or ask your own question.