Doing this in C++

char* cool = "cool";

compiles fine, but gives me a warning:

deprecated conversion from string constant to char*.

I would never willfully use a C-style string over std::string, but just in case I'm asked this question:

is it bad practice to declare a C-style string without the const modifier? If so, why?

  • 5
    BTW this is C not C++ Jul 25, 2016 at 17:40
  • 2
    When compiled the strings are usually located in a read-only memory segment on most modern architectures, just as many other constants Jul 25, 2016 at 17:40
  • 6
    Please pick a language. The answers are different for each language. Jul 25, 2016 at 17:45
  • 29
    This question is appropriately tagged both C and C++, because it is about a difference between C and C++.
    – zwol
    Jul 25, 2016 at 17:47
  • 6
    @NathanOliver To my mind it is so strongly implied that it does not need to be explicit -- or, to put it another way, I would consider it improper to answer this question without spelling out that this is a place where C and C++ are different.
    – zwol
    Jul 25, 2016 at 17:52

8 Answers 8


Yes, this declaration is bad practice, because it allows many ways of accidentally provoking Undefined Behavior by writing to a string literal, including:

cool[0] = 'k';
strcpy(cool, "oops");

On the other hand, this is perfectly fine, since it allocates a non-const array of chars:

char cool[] = "cool";
  • 3
    Indeed, the latter (ok) case is what most people mean by the term "C-style string", which is admittedly ambiguous.
    – Chris Dodd
    Jul 25, 2016 at 17:59
  • 15
    @ChrisDodd I'm not so sure about that. The only meaning I've ever seen for "C-style string" is "array of characters where zero marks the end", which applies equally to char *cool = "cool";, const char *cool = "cool";, char cool[] = "cool"; and const char cool[] = "cool";, and doesn't to all of char cool = "cool\0";, where only the first five of the six characters form a C-style string. I'm not able to find a different definition even with the help of Google.
    – user743382
    Jul 25, 2016 at 22:37
  • 2
    how is char cool[] = "cool"; different from char* cool = "cool";? I would have thought those were basically identical. Jul 26, 2016 at 2:28
  • 6
    The former creates an array and initialises it's elements using the string literal. The latter creates a pointer and sets it to point at the first character in the string literal. So it's safe to write in the former case but not in the latter case.
    – plugwash
    Jul 26, 2016 at 3:53
  • 4
    @Liam, the actual reason is that when you do char* cool = "cool", you only take address of "cool" literal, which may have been allocated in a read-only section of memory and writing there may cause segmentation faults or undefined behavior(suppose the compiler was clever enough to use same literal for all occurences of "cool" in your code). When you do char[] cool = "cool", characters are stored in a read-write section of memory so writing is safe.
    – poe123
    Jul 26, 2016 at 13:02

Yes, in C++ you should always refer to string literals with variables of type const char * or const char [N]. This is also best practice when writing new C code.

String literals are stored in read-only memory, when this is possible; their type is properly const-qualified. C, but not C++, includes a backward compatibility wart where the compiler gives them the type char [N] even though they are stored in read-only memory. This is because string literals are older than the const qualifier. const was invented in the run-up to what's now called "C89" -- the earlier "K&R" form of the language did not have it.

Some C compilers include an optional mode in which the backward compatibility wart is disabled, and char *foo = "..."; will get you the same or a similar diagnostic that it does in C++. GCC spells this mode -Wwrite-strings. I highly recommend it for new code; however, turning it on for old code is liable to require an enormous amount of scutwork for very little benefit.

  • 1
    In C, I'm under the impression that -Wwrite-strings makes you cast the const away if you use a library call that takes a char *. I prefer not using the flag in those situations. Jul 25, 2016 at 17:48
  • 1
    @yellowantphil Yes, but because you'd have to do that anyway when calling the function from C++, most libraries with a C interface have by now been fixed so that you don't need to cast anything. (That is, the arguments are declared const char * unless they're actually going to be modified.)
    – zwol
    Jul 25, 2016 at 17:51
  • I ran into that problem with execv and I'm still not entirely sure why POSIX went with a char *const for the second argument. Jul 25, 2016 at 18:34
  • "String literals are stored in read-only memory" --> read-only memory is not required for a conforming compiler. Writing to these is UB - it may work write, it may fail quietly, it may stop the program, etc. Jul 25, 2016 at 18:47
  • @yellowantphil There's an explanation for that buried in the official specification for execvp (look for the table) but you may also need to read c-faq.com/ansi/constmismatch.html to understand just how nasty the "limitation in C" they're talking about really is.
    – zwol
    Jul 25, 2016 at 19:34

It's bad. It's very bad. To the point this isn't possible to do anymore in C++11.

Modifying the memory of a string literal is undefined behaviour.

  • yea, a const string is locked and i came accross this many times, the behavior of const is almost similar to the behavior of #define.
    – Abr001am
    Nov 25, 2017 at 20:30

First, char* cool = "cool"; is not standard C++. A string literal has the type of const char[n]. So the above line of code breaks const-correctness and should not compile. Some compilers like GCC allow this but issue a warning as it is a hold over from C. MSVC will issue a error since it is a error.

Second, why not let the compiler work for you? If it is marked const then you will get a nice compiler error if you accidentally try to modify it. If you do not then you can get a really nasty run time error which can be much harder to find.

  • No one mentioned that casting the const away is possible and still undefined behavior can occur. It's of course something the programmer will have to do so explicitly that we can blame such programmer for all the issues caused by modifying a string literal. Jul 25, 2016 at 17:43
  • According to this, the type of string literal is not const..
    – Eugene Sh.
    Jul 25, 2016 at 17:43
  • @EugeneSh. Fixed. I only saw the C++ tag and it is not standard C++. Jul 25, 2016 at 17:44
  • @EugeneSh.: That's C. Jul 26, 2016 at 11:10

It is bad because string constants might be contained only once per binary (keyword: stringtable, .strtab). E.g. in

char *cool = "cool";
char *nothot = "cool";

both variables can point to the same memory location. Modifying the contents of one of them might alter the other too, so that after

strcpy(nothot, "warm");

your cool becomes "warm".

In short, it is undefined behaviour.


It is a string literal, therefore it should be constant as memory might be located in read only section. If you have char cool[] = "cool"; then it's not a problem, the memory is yours.


char* cool = "cool"

"cool" will be stored in a read only block (generally in data segment) that is shared among functions. If you try to modify the string "cool" by the point cool you will get a error such as segment error when the program is running. If you use const char* cool = "cool", you will get a error when compile if you try to modify the string.
You can read this page for more information http://www.geeksforgeeks.org/storage-for-strings-in-c/


Its a good practice to write const for strings(especially when you used a string literal) but in C it hardly makes a difference ,it will throw you a warning in c++ but no warning in c,also remember some compilers assume .c extension simply as c but .C as c++,so be careful at such points.otherwise it is a good practice to use const with the case of strings ,so by mistake you don't change the string or try to change a string literal which is stored in read only memory.

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