I can't find much information on const_cast. The only info I could find (on Stack Overflow) is:

The const_cast<>() is used to add/remove const(ness) (or volatile-ness) of a variable.

This makes me nervous. Could using a const_cast cause unexpected behavior? If so, what?

Alternatively, when is it okay to use const_cast?

  • 4
    The top answer overlooks something that might be horribly obvious but is worth stating: It only becomes unsafe if you attempt to modify an originally const object via a de-const-ed reference/pointer. If, instead, you're merely const_casting to work around a poorly (or, in my case, lazily) spec'd API that only acceptd a non-const reference but will only be used in const methods... no problem whatsoever. – underscore_d Dec 22 '15 at 1:39
  • 1
    @underscore_d: A more precise version of the question (and answer) that covers that is: Is it allowed to cast away const on a const-defined object as long as it is not actually modified? – Peter Cordes Feb 5 at 3:30

const_cast is safe only if you're casting a variable that was originally non-const. For example, if you have a function that takes a parameter of a const char *, and you pass in a modifiable char *, it's safe to const_cast that parameter back to a char * and modify it. However, if the original variable was in fact const, then using const_cast will result in undefined behavior.

void func(const char *param, size_t sz, bool modify)
        strncpy(const_cast<char *>(param), sz, "new string");
    printf("param: %s\n", param);


char buffer[16];
const char *unmodifiable = "string constant";
func(buffer, sizeof(buffer), true);  // OK
func(unmodifiable, strlen(unmodifiable), false); // OK
func(unmodifiable, strlen(unmodifiable), true);  // UNDEFINED BEHAVIOR
  • 9
    It's not true. C++ standard. §7.1.​5.1/4 says Except that any class member declared mutable (7.1.1) can be modified, any attempt to modify a const object during its lifetime (3.8) results in undefined behavior Any attempt! There are no words about original variable. – Alexey Malistov Nov 8 '10 at 15:12
  • 19
    @Alexey: The original variable is about what is pointed to or referred to. You can take a const reference to a non-const object, and therefore, casting it to a writable reference is well-defined behaviour as the referred-to object is not actually const. – Puppy Nov 9 '10 at 16:53
  • 42
    @Alexey Malistov: No. An "object" refers to the actual region of storage occupied in memory (§1.7). Taking a const reference to a non-const object does not make the object const. Only in the case of a const reference parameter (not a const pointer parameter) is the compiler allowed to silently make a copy (§5.2.2/5); this is not the case here. – Adam Rosenfield Nov 12 '10 at 16:02
  • 5
    "However, if the original variable was in fact const, then using const_cast will result in undefined behavior" This statement is false. – Lightness Races in Orbit Feb 3 at 15:30
  • 4
    It's not UB to use const_cast to remove const from something that was initially declared const. But it is UB to actually try to write to that object. As long as you just read you are fine and the const_cast in itself does not cause UB. It's a horrible idea, but it's not inherently UB. – Jesper Juhl Feb 3 at 16:13

I can think of two situations where const_cast is safe and useful (there may be other valid cases).

One is when you have a const instance, reference, or pointer, and you want to pass a pointer or reference to an API that is not const-correct, but that you're CERTAIN won't modify the object. You can const_cast the pointer and pass it to the API, trusting that it won't really change anything. For example:

void log(char* text);   // Won't change text -- just const-incorrect

void my_func(const std::string& message)

The other is if you're using an older compiler that doesn't implement 'mutable', and you want to create a class that is logically const but not bitwise const. You can const_cast 'this' within a const method and modify members of your class.

class MyClass
    char cached_data[10000]; // should be mutable
    bool cache_dirty;        // should also be mutable


    char getData(int index) const
        if (cache_dirty)
          MyClass* thisptr = const_cast<MyClass*>(this);
        return cached_data[index];
  • This...doesn't seem to be answering this question. He asked if const_cast can cause undefined behavior, not what useful applications of it are – Michael Mrozek May 21 '14 at 15:21
  • 12
    From the question: "Alternatively, when is it okay to use const_cast?" – Fred Larson May 21 '14 at 15:32
  • As in "when is it not undefined"; he's not looking for examples of when it's useful – Michael Mrozek May 21 '14 at 15:40

I find it hard to believe that that's the only information you could find about const_cast. Quoting from the second Google hit:

If you cast away the constness of an object that has been explicitly declared as const, and attempt to modify it, the results are undefined.

However, if you cast away the constness of an object that has not been explicitly declared as const, you can modify it safely.

  • Grrrreaat answer, combine this with this answer and you get the whole picture. – bobobobo Sep 4 '11 at 14:36
  • hmm. regarding the second statement in your answer, may i ask you how is there a "const"ness for an object which was not explicitly declared as const in the first place?. – hAcKnRoCk Apr 16 '12 at 11:40
  • There are lots of ways to make a non-const object be const, @Iam. For example, pass the object as a const-reference parameter. Or assign it to a pointer-to-const. Or use const_cast. Or call a const method on it. – Rob Kennedy Apr 16 '12 at 13:15

What Adam says. Another example where const_cast can be helpful:

struct sample {
    T& getT() { 
        return const_cast<T&>(static_cast<const sample*>(this)->getT()); 

    const T& getT() const { 
       /* possibly much code here */
       return t; 

    T t;

We first add const to the type this points to, then we call the const version of getT, and then we remove const from the return type, which is valid since t must be non-const (otherwise, the non-const version of getT couldn't have been called). This can be very useful if you got a large function body and you want to avoid redundant code.

  • 1
    I would rather use static cast for the adding constness: static_cast<const sample*>(this). When I'm reading const_cast it means that the code is doing something potentially dangerous, so i try to avoid it's use when possible. – mfazekas Jan 9 '09 at 7:08
  • right, the first can be static_cast, or even be implicit_cast (of boost). i'll fix it using static cast. thanks – Johannes Schaub - litb Jan 9 '09 at 11:56
  • 2
    I go back and forth on whether const_cast or static_cast is better. const_cast can only do what you want: change the cv-qualifiers. static_cast can 'silently' perform other operations that you don't intend. However, the first cast is entirely safe, and static_cast tends to be safer than const_cast. I think this is a situation where the const_cast communicates your intent better, but the static_cast communicates the safety of your actions better. – David Stone Feb 21 '13 at 17:21

The short answer is no, it's not safe.

The long answer is that if you know enough to use it, then it should be safe.

When you're casting, what you are essentially saying is, "I know something the compiler doesn't know." In the case of const_cast, what you are saying is, "Even though this method takes in a non-const reference or pointer, I know that it won't change the parameter I pass it."

So if you do actually know what you are claiming to know in using the cast, then it's fine to use it.


You're destroying any chance at thread-safety, if you start modifying things that the compiler thought were const.

  • 1
    What? If you have immutable (const) objects, you can trivially share them amongst threads. The instant that a piece of your code casts away const-ness, you lose all of your thread safety! Why am I down-modded for this? sigh – Matt Cruikshank Dec 10 '08 at 22:53
  • 6
    Const is certainly a useful tool in making code thread-safe, but it gives no guarantees (except in the case of compile-time constants). Two examples: a const object may have mutable members, and having a const pointer to an object says nothing about whether the object itself could be changing. – James Hopkin Dec 11 '08 at 9:29
  • I think this is a good answer because I didn't think about the compiler optimizer's feelings of trust and security in your use of the word const. const is trust. const_cast is breaking that trust :( – bobobobo Sep 4 '11 at 14:35
  • 1
    Concerning mutable and thread-safety: channel9.msdn.com/posts/… – MFH Jan 21 '13 at 20:25
#include <iostream>
using namespace std;

void f(int* p) {
  cout << *p << endl;

int main(void) {
  const int a = 10;
  const int* b = &a;

  // Function f() expects int*, not const int*
  //   f(b);
  int* c = const_cast<int*>(b);

  // Lvalue is const
  //  *b = 20;

  // Undefined behavior
  //  *c = 30;

  int a1 = 40;
  const int* b1 = &a1;
  int* c1 = const_cast<int*>(b1);

  // Integer a1, the object referred to by c1, has
  // not been declared const
  *c1 = 50;

  return 0;

source: http://publib.boulder.ibm.com/infocenter/comphelp/v8v101/index.jsp?topic=%2Fcom.ibm.xlcpp8a.doc%2Flanguage%2Fref%2Fkeyword_const_cast.htm

  • If the compiler to place in the read-only memory, an error to access this memory and the OS will complete the application. – Mr.Angel Aug 9 '12 at 12:30
  • Accordingly, it is safe to be used only to constants, which were created during the program, because these constants are always placed in the memory allowed for the recording (read-write). – Mr.Angel Aug 9 '12 at 12:39

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