Is there a legitimate use of void* in C++? Or was this introduced because C had it?

Just to recap my thoughts:

Input: If we want to allow multiple input types we can overload functions and methods, alternatively we can define a common base class, or template (thanks for mentioning this in the answers). In both cases the code get's more descriptive and less error prone (provided the base class is implemented in a sane way).

Output: I can't think of any situation where I would prefer to receive void* as opposed to something derived from a known base class.

Just to make it clear what I mean: I'm not specifically asking if there is a use-case for void*, but if there is a case where void* is the best or only available choice. Which has been perfectly answered by several people below.

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    how about the time when you want to have multiple types like int & std::string? – Amir Dec 14 '15 at 17:10
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    @Amir , variant, any, tagged union. Anything which can tell you actual type of content and safer to use. – Revolver_Ocelot Dec 14 '15 at 17:12
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    "C has it" is a strong enough justification, no need to look for more. Avoiding it as much as possible is a good thing in either language. – n. 'pronouns' m. Dec 14 '15 at 17:15
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    Jut one thing: interop with C-style API's is awkward without it. – Martin James Dec 14 '15 at 17:34
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    An interesting usage is type erasure for vectors of pointers – Paolo M Dec 14 '15 at 17:51

void* is at least necessary as the result of ::operator new (also every operator new...) and of malloc and as the argument of the placement new operator.

void* can be thought as the common supertype of every pointer type. So it is not exactly meaning pointer to void, but pointer to anything.

BTW, if you wanted to keep some data for several unrelated global variables, you might use some std::map<void*,int> score; then, after having declared global int x; and double y; and std::string s; do score[&x]=1; and score[&y]=2; and score[&z]=3;

memset wants a void* address (the most generic ones)

Also, POSIX systems have dlsym and its return type evidently should be void*

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    That's a very good point. I forgot to mention that I was thinking more from a language user rather than implementation side. One more thing I don't understand though: Is new a function? I thought of it more as a keyword – magu_ Dec 14 '15 at 17:20
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    new is an operator, like + and sizeof. – Joshua Dec 14 '15 at 17:22
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    Of course memory could be returned through a char * too. They're very close on this aspect, though the meaning is a bit different. – edmz Dec 14 '15 at 17:32
  • @Joshua. Didn't know that. Thank you for teaching me this. Since C++ is written in C++ this is reason enough to have void*. Gotta love this site. Ask one question learn a lot. – magu_ Dec 14 '15 at 17:33
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    @black Back in the old days, C didn't even have a void* type. All standard library functions used char* – Cole Johnson Dec 15 '15 at 7:59

There are multiple reasons to use void*, the 3 most common being:

  1. interacting with a C library using void* in its interface
  2. type-erasure
  3. denoting un-typed memory

In reverse order, denoting un-typed memory with void* (3) instead of char* (or variants) helps preventing accidental pointer arithmetic; there are very few operations available on void* so it usually require casting before being useful. And of course, much like with char* there is no issue with aliasing.

Type-erasure (2) is still used in C++, in conjunction with templates or not:

  • non-generic code helps reducing binary bloat, it's useful in cold paths even in generic code
  • non-generic code is necessary for storage sometimes, even in generic container such as std::function

And obviously, when the interface you deal with uses void* (1), you have little choice.


Oh yes. Even in C++ sometimes we go with void * rather than template<class T*> because sometimes the extra code from the template expansion weighs too much.

Commonly I would use it as the actual implementation of the type, and the template type would inherit from it and wrap the casts.

Also, custom slab allocators (operator new implementations) must use void *. This is one of the reasons why g++ added an extension of permitting pointer arithmatic on void * as though it were of size 1.

  • Thank you for your answer. You're right I forgot to mention templates. But wouldn't templates be even better suited for the task since the rarely introduce a performance penalty?(stackoverflow.com/questions/2442358/…) – magu_ Dec 14 '15 at 17:28
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    Templates introduce a code size penalty, which is also a performance penalty in most cases. – Joshua Dec 14 '15 at 17:30
  • struct wrapper_base {}; template<class T> struct wrapper : public wrapper_base {T val;} typedef wrapper* like_void_ptr; is a minimal void-*-simulator using templates. – user253751 Dec 14 '15 at 20:28
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    @Joshua: You're going to need a citation for "most". – Mehrdad Dec 15 '15 at 3:10
  • @Mehrdad: See L1 cache. – Joshua Dec 15 '15 at 16:10

Input: If we want to allow multiple input types we can overload functions and methods


alternatively we can define a common base class.

This is partially true: what if you can't define a common base class, an interface or similar? To define those you need to have access to the source code, which is often not possible.

You didn't mention templates. However, templates cannot help you with polymorphism: they work with static types i.e. known at compile time.

void* may be consider as the lowest common denominator. In C++, you typically don't need it because (i) you can't inherently do much with it and (ii) there are almost always better solutions.

Even further, you will typically end up on converting it to other concrete types. That's why char * is usually better, although it may indicate that you're expecting a C-style string, rather than a pure block of data. That's whyvoid* is better than char* for that, because it allows implicit cast from other pointer types.

You're supposed to receive some data, work with it and produce an output; to achieve that, you need to know the data you're working with, otherwise you have a different problem which is not the one you were originally solving. Many languages don't have void* and have no problem with that, for instance.

Another legitimate use

When printing pointer addresses with functions like printf the pointer shall have void* type and, therefore, you may need a cast to void*


Yes, it is as useful as any other thing in the language.
As an example, you can use it to erase the type of a class that you are able to statically cast to the right type when needed, in order to have a minimal and flexible interface.

In that response there is an example of use that should give you an idea.
I copy and paste it below for the sake of clarity:

class Dispatcher {
    Dispatcher() { }

    template<class C, void(C::*M)() = C::receive>
    static void invoke(void *instance) {

    template<class C, void(C::*M)() = &C::receive>
    static Dispatcher create(C *instance) {
        Dispatcher d;
        d.fn = &invoke<C, M>;
        d.instance = instance;
        return d;

    void operator()() {

    using Fn = void(*)(void *);
    Fn fn;
    void *instance;

Obviously, this is only one of the bunch of uses of void*.


Interfacing with an external library function which returns a pointer. Here is one for an Ada application.

extern "C" { void* ada_function();}

void* m_status_ptr = ada_function();

This returns a pointer to whatever it was Ada wanted to tell you about. You don't have to do anything fancy with it, you can give it back to Ada to do the next thing. In fact disentangling an Ada pointer in C++ is non-trivial.

  • Couldn't we use auto instead in this case? Assuming that the type is known at compile time. – magu_ Dec 15 '15 at 21:28
  • Ah, nowadays we probably could. That code is from some years ago when I made some Ada wrappers. – RedSonja Dec 16 '15 at 7:05
  • Ada types can be devilish - they make their own, you know, and take a perverse pleasure in making it tricky. I was not allowed to change the interface, that would have been too easy, and it returned some nasty stuff hidden in those void pointers. Ugh. – RedSonja Dec 16 '15 at 7:13

In short, C++ as a strict language (not taking into account C relics like malloc()) requires void* since it has no common parent of all possible types. Unlike ObjC, for example, which has object.

  • malloc and new both return void *, so you would need if even if there was an object class in C++ – Dmitry Grigoryev Dec 14 '15 at 21:01
  • malloc is relict, but in strict languages new should return object * – nredko Dec 14 '15 at 21:07
  • how do you allocate an array of integers then? – Dmitry Grigoryev Dec 15 '15 at 8:01
  • @DmitryGrigoryev operator new() returns void *, but the new expression does not – M.M Dec 15 '15 at 12:57
  • 1. I'm not sure I'd like to see a virtual base class object above every class and type, including int 2. if it's non-virtual EBC, then how is it different from void*? – lorro Jul 28 '16 at 13:21

The first thing that occurs to my mind (which I suspect is a concrete case of a couple of the answers above) is the capability to pass an object instance to a threadproc in Windows.

I've got a couple of C++ classes which need to do this, they have worker thread implementations and the LPVOID parameter in the CreateThread() API gets an address of a static method implementation in the class so the worker thread can do the work with a specific instance of the class. Simple static cast back in the threadproc yields the instance to work with, allowing each instantiated object to have a worker thread from a single static method implementation.


In case of multiple inheritance, if you need to get a pointer to the first byte of a memory chunk occupied by an object, you may dynamic_cast to void*.

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