130

I'm writing an accessor method for a shared pointer in C++ that goes something like this:

class Foo {
public:
    return_type getBar() const {
        return m_bar;
    }

private:
    boost::shared_ptr<Bar> m_bar;
}

So to support the const-ness of getBar() the return type should be a boost::shared_ptr that prevents modification of the Bar it points to. My guess is that shared_ptr<const Bar> is the type I want to return to do that, whereas const shared_ptr<Bar> would prevent reassignment of the pointer itself to point to a different Bar but allow modification of the Bar that it points to... However, I'm not sure. I'd appreciate it if someone who knows for sure could either confirm this, or correct me if I got it wrong. Thanks!

10
  • 3
    It's exactly what you said. You can look at the documentation for operators * and -> to confirm this.
    – syam
    Jul 22 '13 at 17:07
  • 2
    What's the difference between T *const and T const *? The same.
    – user529758
    Jul 22 '13 at 17:09
  • 3
    @H2CO3 Not at all. The const normally modifies what _precedes it, so T *const is a const pointer to T, and T const* is a pointer to const T. And it's best to avoid using const with nothing preceding it. Jul 22 '13 at 17:27
  • 6
    @JamesKanze, that's H2CO3's point: the difference between T *const and T const * is the same as the difference between const shared_ptr<T> and shared_ptr<const T> Jul 22 '13 at 17:29
  • 1
    @JamesKanze Oh but yes. T *const is a const pointer to non-const T, so is const shared_ptr<T>. In contrast, T const * is a non-const pointer to const T, so is shared_ptr<const T>.
    – user529758
    Jul 22 '13 at 17:42
202

You are right. shared_ptr<const T> p; is similar to const T * p; (or, equivalently, T const * p;), that is, the pointed object is const whereas const shared_ptr<T> p; is similar to T* const p; which means that p is const. In summary:

shared_ptr<T> p;             ---> T * p;                                    : nothing is const
const shared_ptr<T> p;       ---> T * const p;                              : p is const
shared_ptr<const T> p;       ---> const T * p;       <=> T const * p;       : *p is const
const shared_ptr<const T> p; ---> const T * const p; <=> T const * const p; : p and *p are const.

The same holds for weak_ptr and unique_ptr.

6
  • 1
    You also answered a question I had in the back of my head about regular pointers (const T* vs. T* const vs. T const *). :) I didn't mention that because I didn't want my quesion on SO to be too broad, and this was the question pertinent to my current task. Anyhow, I think I understand very well now. Thanks! Jul 22 '13 at 17:23
  • 10
    I'm glad it helped. A last tip that I use to remember about const T* p;', 'T const * p; and T * const p. See the * as a separator in the sense that what is const is what is on the same side of the *. Jul 22 '13 at 20:25
  • 5
    My rule of thumb is that const always refers to the thing on the left side of it. If nothing is on the left, it's the thing on the right side.
    – hochl
    Mar 3 '17 at 13:12
  • 1
    hochi - how about const T * p; equivalent to T const * p;?
    – Vlad
    Aug 29 '19 at 17:21
  • Cassio, you can add that in the case of returned type const shared_ptr<T>, it cannot be used in non-const functions while this is not true for const pointers.
    – Vlad
    Aug 29 '19 at 17:22
2

boost::shared_ptr<Bar const> prevents modification of the Bar object through the shared pointer. As a return value, the const in boost::shared_ptr<Bar> const means that you cannot call a non-const function on the returned temporary; if it were for a real pointer (e.g. Bar* const), it would be completely ignored.

In general, even here, the usual rules apply: const modifies what precedes it: in boost::shared_ptr<Bar const>, the Bar; in boost::shared_ptr<Bar> const, it's the instantiation (the expression boost::shared_ptr<Bar> which is const.

2
  • 1
    @gatopeich So you can delete it.
    – Marcin
    Apr 8 '19 at 2:13
  • @Marcin could you ellaborate?
    – gatopeich
    Apr 8 '19 at 9:14
1
#Check this simple code to understand... copy-paste the below code to check on any c++11 compiler

#include <memory>
using namespace std;

class A {
    public:
        int a = 5;
};

shared_ptr<A> f1() {
    const shared_ptr<A> sA(new A);
    shared_ptr<A> sA2(new A);
    sA = sA2; // compile-error
    return sA;
}

shared_ptr<A> f2() {
    shared_ptr<const A> sA(new A);
    sA->a = 4; // compile-error
    return sA;
}

int main(int argc, char** argv) {
    f1();
    f2();
    return 0;
}
1
  • 2
    May I suggest the use of std::make_shared() (since C++14). Dec 6 '18 at 1:33
0

I would like to a simple demostration based on @Cassio Neri's answer:

#include <memory>

int main(){
    std::shared_ptr<int> i = std::make_shared<int>(1);
    std::shared_ptr<int const> ci;

    // i = ci; // compile error
    ci = i;
    std::cout << *i << "\t" << *ci << std::endl; // both will be 1

    *i = 2;
    std::cout << *i << "\t" << *ci << std::endl; // both will be 2

    i = std::make_shared<int>(3);
    std::cout << *i << "\t" << *ci << std::endl; // only *i has changed

    // *ci = 20; // compile error
    ci = std::make_shared<int>(5);
    std::cout << *i << "\t" << *ci << std::endl; // only *ci has changed

}

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