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std::string::c_str() returns a pointer to an array that contains a null-terminated sequence of characters (i.e., a C-string) representing the current value of the string object.

In C++98 it was required that "a program shall not alter any of the characters in this sequence". This was encouraged by returning a const char* .

IN C++11, the "pointer returned points to the internal array currently used by the string object to store the characters that conform its value", and I believe the requirement not to modify its contents has been dropped. Is this true?

Is this code OK in C++11?

using namespace std;

std::vector<char> buf;

void some_func(char* s)
    s[0] = 'X'; //function modifies s[0]

int main()
    string myStr = "hello";
    char* d =;   //C++11
    //char* d = (&buf[0]);  //Above line for C++98
    some_func(d);   //OK in C++98
    some_func(const_cast<char*>(myStr.c_str())); //OK in C++11 ?
    //some_func(myStr.c_str());  //Does not compile in C++98 or C++11
    cout << myStr << endl;  //myStr has been modified
    return 0;
share|improve this question
c_str() still is const char* so fortunately immutable, corresponding to a cacheable result. – Joop Eggen Aug 7 '13 at 21:00
Why do you need this anyway, what's wrong with &myStr.front()? – Jonathan Wakely Aug 7 '13 at 21:05
&myStr[0] works too – Praetorian Aug 7 '13 at 21:15
@AndreKostur Yep, C++11 mandates that the string be stored contiguously in memory. So modifying a range of characters via a pointer to the first is OK, as long as you don't modify the terminating NULL character. – Praetorian Aug 8 '13 at 1:44
… although, reviewing that Q&A, and the Standard, there is actually no way to obtain a pointer to a modifiable range; in effect the characters are const even for a non-const pointer. The contiguity only guarantees that you can read the string as an array. But you cannot assume the terminator is there except after c_str is called and before any non-const member function is called. (Edit: Ah, this is fixed in C++14 so you can modify anything except the terminator, which is generated and returned by operator[] for any index not less than size(), i.e. it returns a fake reference.) – Potatoswatter Aug 8 '13 at 2:05

4 Answers 4

3 Requires: The program shall not alter any of the values stored in the character array.

That requirement is still present as of draft n3337 (The working draft most similar to the published C++11 standard is N3337)

share|improve this answer
I have verified that this is in the published C++11 standard (ISO/IEC 14882-2011). – Graznarak Aug 8 '13 at 0:19
@Graznarak Ah cool, thanks :) – Borgleader Aug 8 '13 at 1:13

In C++11, yes the restriction for c_str() is still in effect. (Note that the return type is const, so no particular restriction is actually required for this function. The const_cast in your program is a big red flag.)

But as for operator[], it appears to be effect only due to an editorial error. Due to a punctuation change slated for C++14, you may modify it. So the interpretation is sort of up to you. Of course doing this is so common that no library implementation would dare break it.

C++11 phrasing:

Returns: *(begin() + pos) if pos < size(), otherwise a reference to an object of type T with value charT(); the referenced value shall not be modified.

C++14 phrasing:

Returns: *(begin() + pos) if pos < size(). Otherwise, returns a reference to an object of type charT with value charT(), where modifying the object leads to undefined behavior.

You can pass c_str() as a read-only reference to a function expecting a C string, exactly as its signature suggests. A function expecting a read-write reference generally expects a given buffer size, and to be able to resize the string by writing a NUL within that buffer, which std::string implementations don't in fact support. If you want to do that, you need to resize the string to include your own NUL terminator, then pass & s[0] which is a read-write reference, then resize it again to remove your NUL terminator and hand the responsibility of termination back to the library.

share|improve this answer
+1 I always assumed that the the referenced value shall not be modified part only applied to the otherwise half, mainly because there wouldn't be a need for const and non-const overloads for operator[] if it covered the whole thing, but I see the ambiguity now. – Praetorian Aug 8 '13 at 2:28
@Praetorian It's worse because C++03 was specified with operator[]() routing through data(), suggesting a built-in unsafe const_cast. If C++11 had added an accidental restriction by editorial error, it would be clearer, but instead the error preserved a defective specification. – Potatoswatter Aug 8 '13 at 2:40

I'd say that if c_str() returns a const char * then its not ok, even if it can be argued to be a gray area by a language lawyer.

The way I see it is simple. The signature of the method states that the pointer it returns should not be used to modify anything.

In addition, as other commenters have pointed out, there are other ways to do the same thing that do not violate any contracts. So it's definitely not ok to do so.

That said, Borgleader has found that the language still says it isn't.

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I have verified that this is in the published C++11 standard

Thank you

what's wrong with &myStr.front()?

string myStr = "hello";
char* p1 = const_cast<char*>(myStr.c_str());
char* p2 = &myStr.front();
p1[0] = 'Y';
p2[1] = 'Z';

It seems that pointers p1 and p2 are exactly the same. Since "The program shall not alter any of the values stored in the character array", it would seem that the last two lines above are both illegal, and possibly dangerous.

At this point, the way I would answer my own question is that it is safest to copy the original std::string into a vector and then pass a pointer to the new array to any function that might possibly change the characters.

I was hoping that that this step might no longer be necessary in C++11, for the reasons I gave in my original post.

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-1: You did a const_cast. Why isn't that enough of a clue that it's a bad idea? Just because the "pointers p1 and p2 are exactly the same" doesn't mean that you should assume that they always will be. Just use front or &[0], and stop lying to your compiler. Your coding style is horrible; just do it the right way please. – Nicol Bolas Aug 8 '13 at 1:45
There's no need for the const_cast, those should be avoided as much as possible; use front() or operator[] to get a reference to the first element. Also, there's no need for copying the string into a vector to modify it as long as you make sure the string is large enough to be written to, and you don't modify the terminating NULL character – Praetorian Aug 8 '13 at 1:53
@user2662157: "the standard is that "The program shall not alter any of the values stored in the character array."" It says that for the array returned by c_str, not for the std::string in general. Context is important. – Nicol Bolas Aug 8 '13 at 2:18
@user2662157: "or an identical pointer" No, that's not how the standard works. The standard doesn't care if a pointer just so happens to be identical in value to another. The standard says what it says. You are forbidden from modifying the string via the pointer returned by c_str. Another function may return a pointer that you are allowed to modify. The fact that these two pointers may have (or even are required to have) the same pointer value is completely irrelevant to what the standard says. You can modify through one of them, and you can't modify through the other. – Nicol Bolas Aug 8 '13 at 10:42
I apologize. My last two comments are wrong. In this case, c_str may modify the internal array (in particular, the terminal '\0") before returning the pointer. So it is quite correct to say that it is completely irrelevant that another pointer would have the same value. – user2662157 Aug 8 '13 at 17:03

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