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Let's say you have a class

    class C 
      int * i;


         C(int * v):i(v) {};

         void method() const;  //this method does not change i
         void method();        //this method changes i

Now you may want to define const instance of this class

    const int * k = whatever;
    const C c1(k); //this will fail

but this will fail because of non-const int C's constructor C(int * v)

so you define a const int constructor

    C(const int * v):i(v) {}; //this will fail also

But this will fail also since C's member "int * i" is non-const.

What to do in such cases? Use mutable? Casting? Prepare const version of class?

edit: After discussion with Pavel (below) I investigated this problem a bit. To me what C++ does is not correct. Pointer target should be a strict type, that means that you could not for example do the following:

int i;
const int * ptr;
ptr = & i;

In this case language grammar treats const as a promise not to change pointer's target. In addition int * const ptr is a promise not to change pointer value itself. Thus you have two places where const can be applied. Then you may want your class to model a pointer (why not). And here things are falling into pieces. C++ grammar provides const methods which are able to promise not to change field's values itself but there is no grammar to point out that your method will not change targets of your in-class pointers.

A workaround is to define two classes const_C and C for example. It isn't a royal road however. With templates, their partial specializations it's hard not to stuck into a mess. Also all possible arguments variations like const const_C & arg, const C & arg, const_C & arg, C & arg don't look pretty. I really don't know what to do. Use separate classes or const_casts, each way seems to be wrong.

In both cases should I mark methods which don't modify pointer's target as const? Or just follow traditional path that const method doesn't change object's state itself (const method don't care about pointer target). Then in my case all methods would be const, because class is modelling a pointer thus pointer itself is T * const. But clearly some of them modify pointer's target and others do not.

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mutable won't help you here because it only applied to fields themselves, not to what they point to. – Pavel Minaev Nov 9 '09 at 21:15
I have a feeling that something doesn't fit in const-correctness. There must be misconception somewhere. – doc Nov 9 '09 at 21:48

7 Answers 7

up vote 5 down vote accepted

Your example doesn't fail, k is passed by value. The member i is 'implicitly constant' as direct members of C can't be changed when the instance is constant.
Constness says that you can't change members after initialization, but initializing them with values in the initialization list is of course allowed - how else would you give them a value?

What doesn't work is invoking the constructor without making it public though ;)

update addressing updated question:

Yes, C++ forces you into some verboseness sometimes, but const correctness is a common standard behaviour that you can't just redefine without breaking expectations. Pavels answer already explains one common idiom, which is used in proven libraries like the STL, for working around this situation.

Sometimes you have to just accept that languages have limitations and still deal with the expectations of the users of the interface, even if that means applying an apparently sub-optimal solution.

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+1 for the sharp eyes :) – Anders Karlsson Nov 9 '09 at 6:06
Of course, my fault. I modified an example to use pointers – doc Nov 9 '09 at 6:07
+1. Simple and informative. Just don't know what to add. – Dmitriy Matveev Nov 9 '09 at 6:07
I really apologize for my absend-mindednes. Because what said Pavel Minaev I must unaccept your answer. After all I think it's not a bad question and I didn't find satisfactory explanation on the net. – doc Nov 9 '09 at 22:05
Sure, accept what fits best for you. – Georg Fritzsche Nov 9 '09 at 22:27

Sounds like you want an object that can wrap either int* (and then behave as non-const), or int const* (and then behave as const). You can't really do it properly with a single class.

In fact, the very notion that const applied to your class should change its semantics like that is wrong - if your class models a pointer or an iterator (if it wraps a pointer, it's likely to be the case), then const applied to it should only mean that it cannot be changed itself, and should not imply anything regarding the value pointed to. You should consider following what STL does for its containers - it's precisely why it has distinct iterator and const_iterator classes, with both being distinct, but the former being implicitly convertible to the latter. As well, in STL, const iterator isn't the same as const_iterator! So just do the same.

[EDIT] Here's a tricky way to maximally reuse code between C and const_C while ensuring const-correctness throughout, and not delving into U.B. (with const_cast):

template<class T, bool IsConst>
struct pointer_to_maybe_const;

template<class T>
struct pointer_to_maybe_const<T, true> { typedef const T* type; };

template<class T>
struct pointer_to_maybe_const<T, false> { typedef T* type; };

template<bool IsConst>
struct C_fields {
   typename pointer_to_maybe_const<int, IsConst>::type i;
   // repeat for all fields

template<class Derived>
class const_C_base {
    int method() const { // non-mutating method example
        return *self().i;
    const Derived& self() const { return *static_cast<const Derived*>(this); }

template<class Derived>
class C_base : public const_C_base<Derived> {
    int method() { // mutating method example
        return ++*self().i;
    Derived& self() { return *static_cast<Derived*>(this); }

class const_C : public const_C_base<const_C>, private C_fields<true> {
    friend class const_C_base<const_C>;

class C : public C_base<C>, private C_fields<false> {
    friend class C_base<C>;

If you actually have few fields, it may be easier to duplicate them in both classes rather than going for a struct. If there are many, but they are all of the same type, then it is simpler to pass that type as a type parameter directly, and not bother with const wrapper template.

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Yes you are right. So a separate class would be the best solution. Is it advisable to inherit everything after C or you have to rewrite all the code? Consider C has dozens of int * pointers - then inherited version const_C would waste space allocated by C's non-const members. On the other hand repeating all the code is a cumbersome. Any sugestions? – doc Nov 9 '09 at 21:28
The real problem with inheritance isn't duplication of fields - you can refactor those into a struct, and then apply const to that wholesale in your const_C version. The problem is code reuse. First of all, inheriting const_C from C doesn't make sense - you want C to be implicitly convertible to const_C, not the other way around, so you'd have to derive C from const_C if you want to use inheritance for that. But then the problem is that all fields you inherit from const_C will also be const, and mutating C methods will have nothing to work with... – Pavel Minaev Nov 9 '09 at 21:56
For the nth time I apologize for my terrible expression. Of course you inherit after const_C, then consider that const_C has (maybe not dozens but a few) const ints or any non-pointer const data which should be allocated on stack. In such case this is also a problem for extended class if it has to redefine all of them to non-const. And code reuse is of course the second problem. – doc Nov 9 '09 at 22:18
In case of fields one may use mutable. But many docs say that mutable should be used if field is logicaly const but for some reason needs update. And here it would be mutable by design. – doc Nov 9 '09 at 22:39
mutable is used when object is logically const, but some of its fields aren't (e.g. if said fields serve as a cache of sorts). – Pavel Minaev Nov 9 '09 at 23:40

Your question does not make sense. Where did you get all these "this will fail" predictions? None of them are even remotely true.

Firstly, it is completely irrelevant whether the constructor's parameter is declared const or not. When you are passing by value (as in your case) you can pass a const object as an argument in any case, regardless of whether the parameter is declared as const or not.

Secondly, from the constructor's point of view, the object is NOT constant. Regardless of what kind of object you are constructing (constant or not), from within the constructor the object is never constant. So there's no need for mutable or anything.

Why don't you just try compiling your code (to see that nothing will fail), instead of making strange ungrounded predictions that something "will fail"?

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sorry it was a mistake. Class is using pointers so it isn't pass by value. I have real class of this kind, I just wanted to show it clean and oversimplified an example. – doc Nov 9 '09 at 6:18

A const int* is not the same as a int* const. When your class is const, you have the latter (constant pointer to mutable integer). What you're passing is the former (mutable pointer to constant integer). The two are not interchangeable, for obvious reasons.

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When you instantiate

const C c1(...)

Because c1 is const, its member i turns in to:

int* const i;

As someone else mentioned, this is called implicit const.

Now, later in your example, you attempt to pass a const int*. So your constructor is basically doing this:

const int* whatever = ...;
int* const i = whatever; // error

The reason you get an error is because you can't cast const to non-const. The 'whatever' pointer is not allowed to change the thing it points to (the int part is const). The 'i' pointer is allowed to change what it points to, but cannot itself be changed (the pointer part is const).

You also mention wanting your class to model a pointer. The STL does this with iterators. The model some implementations use is having a class called 'const_iterator' which hides the real pointer and only supplies const methods to access the pointed-to data. Then there's also an 'iterator' class which inherits from 'const_iterator', adding non-const overloads. This works nicely - it's a custom class which allows the same constness as pointers, where the types mirror pointers like so:

  • iterator -> T*
  • const iterator -> T* const
  • const_iterator -> const T*
  • const const_iterator -> const T* const

Hopefully that makes sense :)

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I have read gcc sources for iterator classes and I found that this classes are so simple that they are reproducing the code for each method. Not my case at all. Also note that iterator doesn't model a pointer, it models a bunch of pointers. In my case class always consists const pointer (that is T * const), thus I don't need four variations of const. – doc Dec 3 '09 at 12:32

OK here's what I have done so far. To allow inheritance after const version of class without const_casts or additional space overhead I created an union which basically looks like ths:

template <typename T>
union MutatedPtr
	const T * const_ptr;
	T * ptr;

	 * Conversion constructor.
	 * @param ptr pointer.
	MutatedPtr(const T * ptr): const_ptr(ptr) {};

	 * Conversion to T *.
	operator T *() {return ptr;}

	 * Conversion to const T *.
	operator const T *() const {return const_ptr;}

When MutatedPtr field is declared, it ends up so that in const methods const_ptr is returned, while non-const ones get plain ptr. It delegates method's const-ness to pointer target which makes sense in my case.

Any comments?

BTW you can of course do similar thing with non-pointer types or even methods, so it looks that introducing mutable keyword wasn't necessary(?)

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The problem with this is that it won't portably work if you access the same MutatedPtr first as const, and then as non-const (which is what happens when it's a member of a const object - it will be non-const in constructor, but const in other methods). The reason why this is a problem is that in C++, you can only read from the union member that was last written to - i.e. if ctor writes into ptr, then reading later from const_ptr invokes U.B. – Pavel Minaev Dec 16 '09 at 8:34
There is an exception to that if union has two (or more) structs. If those structs share a "common initial sequence" of members, then that common sequence can be accessed from either struct once one of them is assigned. To be "common" the sequence of fields must contain "layout-compatible" types in the same order. And any type T is layout-compatible with const T. So if you wrap those pointers in structs, then it should be fully conformant. – Pavel Minaev Dec 16 '09 at 8:35
The reason why this won't work in general (and can't replace mutable for all cases) is because you cannot have members of types with non-trivial constructors or destructors in unions (so e.g. no std::string). – Pavel Minaev Dec 16 '09 at 8:36
From what I found, you are allowed to read from any member of union. K&R (I know it's C) states that result of this is implementation defined. Open Standards C++ is even more laconic. Other books I have don't say much more. I think it will work on 99.(9)% compilers and for the rest I have added assert(ptr == const_ptr) in constructor. I'm wondering if C++'s anonymous unions aren't free of this restrictions. – doc Dec 17 '09 at 2:40
I have also found that you can have types with non-trivial constructors in unions, you just have to provide custom constructor, destructor, assignment operator and copy constructor. Here's example from Open Standards C++, which contains std::string as member of union: union U { int i; float f; std::string s; }; "Since std::string (21.3) declares non-trivial versions of all of the special member functions, U will have an implicitly deleted default constructor, copy constructor, copy assignment operator, and destructor. To use U, some or all of these member functions must be user-declared." – doc Dec 17 '09 at 2:48

I've run into the same unfortunate issue and after lamenting the lack of a const constructor in C++ I've come to the conclusion that two templatization is the best course, at least in terms of reuse.

A very simplified version of my case/solution is:

 template< typename DataPtrT >
 struct BaseImage
     BaseImage( const DataPtrT & data ) : m_data( data ) {}

     DataPtrT getData() { return m_data; } // notice that if DataPtrT is const 
                                           // internally, this will return
                                           // the same const type
     DataPtrT m_data;

 template< typename DataPtrT >
 struct DerivedImage : public BaseImage<DataPtrT>

There is a very unfortunate loss of class inheritance but in my case it was acceptable to make a sort of casting operator to be able to cast between const and non-const types with some explicit knowledge of how to do the conversion under the hood. That mixed with some appropriate use of copy constructors and/or overloaded dereference operator might get you to where you want to be.

 template< typename OutTypeT, typename inTypeT )
 image_cast< shared_ptr<OutTypeT> >( const shared_ptr<InTypeT> & inImage )
     return shared_ptr<OutTypeT>( new OutTypeT( inImage->getData() ) );
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