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I came across this strange code snippet which compiles fine:

class Car
{
    public:
    int speed;
};

int main()
{
    int Car::*pSpeed = &Car::speed;
    return 0;
}

Why does C++ have this pointer to a non-static data member of a class? What is the use of this strange pointer in real code?

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Here's where I found it, confused me too...but makes sense now: stackoverflow.com/a/982941/211160 –  HostileFork Jul 12 '12 at 6:03

10 Answers 10

up vote 62 down vote accepted

It's a "pointer to member" - the following code illustrates its use:

#include <iostream>
using namespace std;

class Car
{
    public:
    int speed;
};

int main()
{
    int Car::*pSpeed = &Car::speed;

    Car c1;
    c1.speed = 1;       // direct access
    cout << "speed is " << c1.speed << endl;
    c1.*pSpeed = 2;     // access via pointer to member
    cout << "speed is " << c1.speed << endl;
    return 0;
}

As to why you would want to do that, well it gives you another level of indirection that can solve some tricky problems. But to be honest, I've never had to use them in my own code.

Edit: I can't think off-hand of a convincing use for pointers to member data. Pointer to member functions can be used in pluggable architectures, but once again producing an example in a small space defeats me. The following is my best (untested) try - an Apply function that would do some pre &post processing before applying a user-selected member function to an object:

void Apply( SomeClass * c, SomeClass::*func() ) {
    // do hefty pre-call processing
    c->*func();  // call user specified function
    // do hefty post-call processing
}
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1  
Could you show an example of a tricky situation where this is useful? Thanks. –  Ashwin Mar 22 '09 at 9:31
    
I have an example of using pointer-to-member in a Traits class in another SO answer. –  Mike DeSimone Apr 13 '11 at 19:08
    
An example is writing a "callback"-type class for some event-based system. CEGUI’s UI event subscription system, for example, takes a templated callback that stores a pointer to a member function of your choosing, so that you can specify a method to handle the event. –  Benji XVI Dec 28 '12 at 21:03
    
There is a pretty cool example of pointer-to-data-member usage in a template function in this code –  alveko Jun 6 '13 at 22:43
    
See my example in the answer below. –  Tom Jan 13 at 16:27

Another application are intrusive lists. The element type can tell the list what its next/prev pointers are. So the list does not use hard-coded names but can still use existing pointers:

// say this is some existing structure. And we want to use
// a list. We can tell it that the next pointer
// is apple::next.
struct apple {
    int data;
    apple * next;
};

// simple example of a minimal intrusive list. Could specify the
// member pointer as template argument too, if we wanted:
// template<typename E, E *E::*next_ptr>
template<typename E>
struct List {
    List(E *E::*next_ptr):head(0), next_ptr(next_ptr) { }

    void add(E &e) {
        // access its next pointer by the member pointer
        e.*next_ptr = head;
        head = &e;
    }

    E * head;
    E *E::*next_ptr;
};

int main() {
    List<apple> lst(&apple::next);

    apple a;
    lst.add(a);
}
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If this is truly a linked list wouldn't you want something like this: void add(E* e) { e->*next_ptr = head; head = e; } ?? –  eeeeaaii Aug 25 '11 at 16:56
    
@eee I recommend you to read about reference parameters. What I did is basically equivalent to what you did. –  Johannes Schaub - litb Aug 25 '11 at 18:55
    
+1 for your code example, but I didn't see any necessity for the use of pointer-to-member, any other example? –  Alcott Aug 14 '12 at 8:32
    
@Alcott: You can apply it to other linked-list-like structures where the next pointer is not named next. –  icktoofay May 18 '13 at 23:13

You can later access this member, on any instance:

int main()
{    
  int Car::*pSpeed = &Car::speed;    
  Car myCar;
  Car yourCar;

  int mySpeed = myCar.*pSpeed;
  int yourSpeed = yourCar.*pSpeed;

  assert(mySpeed > yourSpeed); // ;-)

  return 0;
}

Note that you do need an instance to call it on, so it does not work like a delegate.
It is used rarely, I've needed it maybe once or twice in all my years.

Normally using an interface (i.e. a pure base class in C++) is the better design choice.

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But surely this is just bad practice? should do something like youcar.setspeed(mycar.getpspeed) –  thecoshman Oct 6 '10 at 21:08
2  
@thecoshman: entirely depends - hiding data members behind set/get methods is not encapsulation and merely a milkmaids attempt at interface abstraction. In many scenarios, "denormalization" to public members is a reasonable choice. But that discussion probably exceeds the confines of the comment functionality. –  peterchen Oct 12 '10 at 15:21
1  
+1 for pointing out, if I understand correctly, that this is a pointer to a member of any instance, and not a pointer to a specific value of one instance, which is the part I was completely missing. –  OpenLearner May 21 '13 at 9:49
    
@Fellowshee You do understand correctly :) (emphasized that in the answer). –  peterchen May 22 '13 at 16:58

This is the simplest example I can think of that conveys the rare cases where this feature is pertinent:

#include <iostream>

class bowl {
public:
    int apples;
    int oranges;
};

int count_fruit(bowl * begin, bowl * end, int bowl::*fruit)
{
    int count = 0;
    for (bowl * iterator = begin; iterator != end; ++ iterator)
        count += iterator->*fruit;
    return count;
}

int main()
{
    bowl bowls[2] = {
        { 1, 2 },
        { 3, 5 }
    };
    std::cout << "I have " << count_fruit(bowls, bowls + 2, & bowl::apples) << " apples\n";
    std::cout << "I have " << count_fruit(bowls, bowls + 2, & bowl::oranges) << " oranges\n";
    return 0;
}

The thing to note here is the pointer passed in to count_fruit. This saves you having to write separate count_apples and count_oranges functions.

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Shouldn't it be &bowls.apples and &bowls.oranges? &bowl::apples and &bowl::oranges doesn't point to anything. –  Dan Nissenbaum Mar 30 at 9:20
1  
&bowl::apples and &bowl::oranges do not point to members of an object; they point to members of a class. They need to be combined with a pointer to an actual object before they point to something. That combination is achieved with the ->* operator. –  JMcF Mar 30 at 20:56
    
It's clear now; I wasn't seeing straight. Thanks. –  Dan Nissenbaum Mar 30 at 21:41
    
(+1) for the best and easy to understand example I've seen so far about pointer to member. –  Wake up Brazil Oct 14 at 16:29

IBM has some more documentation on how to use this. Briefly, you're using the pointer as an offset into the class. You can't use these pointers apart from the class they refer to, so:

  int Car::*pSpeed = &Car::speed;
  Car mycar;
  mycar.*pSpeed = 65;

It seems a little obscure, but one possible application is if you're trying to write code for deserializing generic data into many different object types, and your code needs to handle object types that it knows absolutely nothing about (for example, your code is in a library, and the objects into which you deserialize were created by a user of your library). The member pointers give you a generic, semi-legible way of referring to the individual data member offsets, without having to resort to typeless void * tricks the way you might for C structs.

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Could you share a code snippet example where this construct is useful? Thanks. –  Ashwin Mar 22 '09 at 9:32
1  
+1 for finding a reasonable use case –  dmckee Mar 22 '09 at 16:24
    
I'm currently doing alot of this due to doing some DCOM work and using managed resource classes which involves doing a bit of work before each call, and using data members for internal representation to send off to com, plus templating,makes a lot of boiler plate code much smaller –  Dan Aug 10 '09 at 21:30
1  
+1 for the key point: "Briefly, you're using the pointer as an offset into the class." –  Samaursa Nov 29 '12 at 3:53

It makes it possible to bind member variables and functions in the uniform manner. The following is example with your Car class. More common usage would be binding std::pair::first and ::second when using in STL algorithms and Boost on a map.

#include <list>
#include <algorithm>
#include <iostream>
#include <iterator>
#include <boost/lambda/lambda.hpp>
#include <boost/lambda/bind.hpp>


class Car {
public:
    Car(int s): speed(s) {}
    void drive() {
        std::cout << "Driving at " << speed << " km/h" << std::endl;
    }
    int speed;
};

int main() {

    using namespace std;
    using namespace boost::lambda;

    list<Car> l;
    l.push_back(Car(10));
    l.push_back(Car(140));
    l.push_back(Car(130));
    l.push_back(Car(60));

    // Speeding cars
    list<Car> s;

    // Binding a value to a member variable.
    // Find all cars with speed over 60 km/h.
    remove_copy_if(l.begin(), l.end(),
                   back_inserter(s),
                   bind(&Car::speed, _1) <= 60);

    // Binding a value to a member function.
    // Call a function on each car.
    for_each(s.begin(), s.end(), bind(&Car::drive, _1));

    return 0;
}
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Here's a real-world example I am working on right now, from signal processing / control systems:

Suppose you have some structure that represents the data you are collecting:

struct Sample {
    time_t time;
    double value1;
    double value2;
    double value3;
};

Now suppose that you stuff them into a vector:

std::vector<Sample> samples;
... fill the vector ...

Now suppose that you want to calculate some function (say the mean) of one of the variables over a range of samples, and you want to factor this mean calculation into a function. The pointer-to-member makes it easy:

double Mean(std::vector<Sample>::const_iterator begin, 
    std::vector<Sample>::const_iterator end,
    double Sample::* var)
{
    float mean = 0;
    int samples = 0;
    for(; begin != end; begin++) {
        const Sample& s = *begin;
        mean += s.*var;
        samples++;
    }
    mean /= samples;
    return mean;
}

...
double mean = Mean(samples.begin(), samples.end(), &Sample::value2);

And, of course, you can template it, though it gets a bit messy (I've recast it as a struct to get the typedefs in; I guess there'd be a way with a template function, but its a bit more readable this way):

template<typename T>
struct Mean {
    typedef std::vector<T> Tvector;
    typedef typename std::vector<T>::const_iterator Titer;
    double operator()(Titer begin, Titer end, double T::* var) {
        float sum = 0;
        int samples = 0;
        for( ; begin != end; begin++ ) {
            const T& s = *begin;
            sum += s.*var;
            samples++;
        }
        return sum / samples;
    }
};

...

Mean<Sample> m;
double mean = m(samples.begin(), samples.end(), &Sample::value2);

EDIT - The above code has performance implications

You should note, as I soon discovered, that the code above has some serious performance implications. The summary is that if you're calculating a summary statistic on a time series, or calculating an FFT etc, then you should store the values for each variable contiguously in memory. Otherwise, iterating over the series will cause a cache miss for every value retrieved.

Consider the performance of this code:

struct Sample {
  float w, x, y, z;
};

std::vector<Sample> series = ...;

float sum = 0;
int samples = 0;
for(auto it = series.begin(); it != series.end(); it++) {
  sum += *it.x;
  samples++;
}
float mean = sum / samples;

On many architectures, one instance of Sample will fill a cache line. So on each iteration of the loop, one sample will be pulled from memory into the cache. 4 bytes from the cache line will be used and the rest thrown away, and the next iteration will result in another cache miss, memory access and so on.

Much better to do this:

struct Samples {
  std::vector<float> w, x, y, z;
};

Samples series = ...;

float sum = 0;
float samples = 0;
for(auto it = series.x.begin(); it != series.x.end(); it++) {
  sum += *it;
  samples++;
}
float mean = sum / samples;

Now when the first x value is loaded from memory, the next three will also be loaded into the cache (supposing suitable alignment), meaning you don't need any values loaded for the next three iterations.

The above algorithm can be improved somewhat further through the use of SIMD instructions on eg SSE2 architectures. However, these work much better if the values are all contiguous in memory and you can use a single instruction to load four samples together (more in later SSE versions).

YMMV - design your data structures to suit your algorithm.

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This is excellent. I'm about to implement something very similar, and now I don't have to figure out the strange syntax! Thanks! –  SchighSchagh Mar 26 '13 at 2:47

You can use an array of pointer to (homogeneous) member data to enable a dual, named-member (i.e. x.data) and array-subscript (i.e. x[idx]) interface.

#include <cassert>
#include <cstddef>

struct vector3 {
    float x;
    float y;
    float z;

    float& operator[](std::size_t idx) {
    	static float vector3::*component[3] = {
    		&vector3::x, &vector3::y, &vector3::z
    	};
    	return this->*component[idx];
    }
};

int main()
{
    vector3 v = { 0.0f, 1.0f, 2.0f };

    assert(&v[0] == &v.x);
    assert(&v[1] == &v.y);
    assert(&v[2] == &v.z);

    for (std::size_t i = 0; i < 3; ++i) {
    	v[i] += 1.0f;
    }

    assert(v.x == 1.0f);
    assert(v.y == 2.0f);
    assert(v.z == 3.0f);

    return 0;
}
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One way I've used it is if I have two implementations of how to do something in a class and I want to choose one at run-time without having to continually go through an if statement i.e.

class Algorithm
{
public:
    Algorithm() : m_impFn( &Algorithm::implementationA ) {}
    void frequentlyCalled()
    {
        // Avoid if ( using A ) else if ( using B ) type of thing
        (this->*m_impFn)();
    }
private:
    void implementationA() { /*...*/ }
    void implementationB() { /*...*/ }

    typedef void ( Algorithm::*IMP_FN ) ();
    IMP_FN m_impFn;
};

Obviously this is only practically useful if you feel the code is being hammered enough that the if statement is slowing things done eg. deep in the guts of some intensive algorithm somewhere. I still think it's more elegant than the if statement even in situations where it has no practical use but that's just my opnion.

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I think you'd only want to do this if the member data was pretty large (e.g., an object of another pretty hefty class), and you have some external routine which only works on references to objects of that class. You don't want to copy the member object, so this lets you pass it around.

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