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I am little confused with the applicability of reinterpret_cast vs static_cast. From what I have read the general rules are to use static cast when the types can be interpreted at compile time hence the word static. This is the cast the C++ compiler uses internally for implicit casts also.

reinterpret_cast are applicable in two scenarios, convert integer types to pointer types and vice versa or to convert one pointer type to another. The general idea I get is this is unportable and should be avoided.

Where I am a little confused is one usage which I need, I am calling C++ from C and the C code needs to hold on to the C++ object so basically it holds a void*. What cast should be used to convert between the void * and the Class type?

I have seen usage of both static_cast and reinterpret_cast? Though from what I have been reading it appears static is better as the cast can happen at compile time? Though it says to use reinterpret_cast to convert from one pointer type to another?

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7 Answers 7

up vote 198 down vote accepted

The C++ standard guarantees the following:

static_casting a pointer to and from void* preserves the address. That is, in the following, a, b and c all point to the same address:

int* a = new int();
void* b = static_cast<void*>(a);
int* c = static_cast<int*>(b);

reinterpret_cast only guarantees that if you cast a pointer to a different type, and then reinterpret_cast it back to the original type, you get the original value. So in the following:

int* a = new int();
void* b = reinterpret_cast<void*>(a);
int* c = reinterpret_cast<int*>(b);

a and c contain the same value, but the value of b is unspecified. (in practice it will typically contain the same address as a and c, but that's not specified in the standard, and it may not be true on machines with more complex memory systems.)

For casting to and from void*, static_cast should be preferred.

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I like the fact that 'b' is undefined. It stops you doing silly things with it. If you cast something to another pointer type you are asking for problems and the fact that you can not depend on it makes you more careful. If you had used static_cast<> above what use is the 'b' anyway? –  Loki Astari Feb 21 '09 at 21:27
I thought that reinterpret_cast<> guaranteed the same bit pattern. (which is not the same as a valid pointer to another type). –  Loki Astari Feb 21 '09 at 21:37
@Martin - reinterpret_cast<> is not guaranteed to result in the same bit pattern. "The mapping performed by reinterpret_cast<> is implementation defined." (C++03 5.3.10). However, the standard notes that "it is intended to be unsurprising". –  Michael Burr Apr 30 '09 at 3:35
the value of b is not unspecified anymore in C++11 when using reinterpret_cast. And in C++03 a cast of int* to void* was forbidden to be done with reinterpret_cast (although compilers did not implement that and it was impractical, hence was changed for C++11). –  Johannes Schaub - litb Oct 28 '11 at 23:20
hmm, true about reinterpret-casting to/from void*. I wonder why I thought that was legal when I wrote this. –  jalf Oct 29 '11 at 9:29

One case when reinterpret_cast is necessary is when interfacing with opaque data types. This occurs frequently in vendor APIs over which the programmer has no control. Here's a contrived example where a vendor provides an API for storing and retrieving arbitrary global data:

// vendor.hpp
typedef struct _Opaque * VendorGlobalUserData;
void VendorSetUserData(VendorGlobalUserData p);
VendorGlobalUserData VendorGetUserData();

To use this API, the programmer must cast their data to VendorGlobalUserData and back again. static_cast won't work, one must use reinterpret_cast:

// main.cpp
#include "vendor.hpp"
#include <iostream>
using namespace std;

struct MyUserData {
    MyUserData() : m(42) {}
    int m;

int main() {
    MyUserData u;

        // store global data
    VendorGlobalUserData d1;
//  d1 = &u;                                          // compile error
//  d1 = static_cast<VendorGlobalUserData>(&u);       // compile error
    d1 = reinterpret_cast<VendorGlobalUserData>(&u);  // ok

        // do other stuff...

        // retrieve global data
    VendorGlobalUserData d2 = VendorGetUserData();
    MyUserData * p = 0;
//  p = d2;                                           // compile error
//  p = static_cast<MyUserData *>(d2);                // compile error
    p = reinterpret_cast<MyUserData *>(d2);           // ok

    if (p) { cout << p->m << endl; }
    return 0;

Below is a contrived implementation of the sample API:

// vendor.cpp
static VendorGlobalUserData g = 0;
void VendorSetUserData(VendorGlobalUserData p) { g = p; }
VendorGlobalUserData VendorGetUserData() { return g; }
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Yep, that's about the only meaningful use of reinterpret_cast I can think of. –  jalf Feb 21 '09 at 21:36
This may be a late question, but why doesn't the vendor API use void* for that? –  Xeo Oct 29 '11 at 1:09
@Xeo because the vendor API sucks. –  user1203803 Apr 18 '12 at 8:10
@Xeo They don't use void * because then they lose (some) type-checking at compile time. –  jesup Aug 14 '14 at 6:17

The meaning of reinterpret_cast is not defined by the C++ standard. Hence, in theory a reinterpret_cast could crash your program. In practice compilers try to do what you expect, which is to interpret the bits of what you are passing in as if they were the type you are casting to. If you know what the compilers you are going to use do with reinterpret_cast you can use it, but to say that it is portable would be lying.

For the case you describe, and pretty much any case where you might consider reinterpret_cast, you can use static_cast or some other alternative instead. Among other things the standard has this to say about what you can expect of static_cast (§5.2.9):

An rvalue of type “pointer to cv void” can be explicitly converted to a pointer to object type. A value of type pointer to object converted to “pointer to cv void” and back to the original pointer type will have its original value.

So for your use case, it seems fairly clear that the standardization committee intended for you to use static_cast.

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Not quite crash your program. The standard offers a few guarantees about reinterpret_cast. Just not as many as people often expect. –  jalf Feb 21 '09 at 16:43
Not if you use it properly. That is, reinterpret_cast from A to B to A is perfectly safe and well-defined. But the value of B is unspecified, and yes, if you rely on that, bad things could happen. But the cast itself is safe enough, as long as you only used it in the way the standard allows. ;) –  jalf Feb 21 '09 at 19:10
lol, I suspect that reinterpret_crash might indeed crash your program. But reinterpret_cast won't. ;) –  jalf Feb 21 '09 at 21:35
<irony>I tried it on my compiler, and somehow, it refused to compile reinterpret_crash. No way a compiler bug will stop me from crashing my reinterpreting program. I'll report a bug ASAP!</irony> –  paercebal Jul 11 '10 at 11:56
@paercebal template<class T, U> T reinterpret_crash(U a) { return *(T*)nullptr; } –  user142019 Jan 14 '12 at 10:41
template <class outType, class inType>
outType safe_cast(inType pointer)
    void* temp = static_cast<void*>(pointer);
    return static_cast<outType>(temp);

I tried to conclude and wrote a simple safe cast using templates. Note that this solution doesn't guarantee to cast pointers on a functions.

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You could use reinterprete_cast to check inheritance at compile time.
Look here: Using reinterpret_cast to check inheritance at compile time

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Never. You never need to use it ever. You may use static_cast to convert from void* (here is a demo http://ideone.com/Ic04w). Never EVER use reinterpret_cast.

Its meant for hardware access. Are you writing a device driver? I'm pretty sure you aren't. So writing the below is something you won't be doing. You are allow to store pointers into ints big enough to old it and we all know we can display ints to the user or dump it to a file for diagnostics. So maybe for debugging pointer arithmetic or comparing them to another but that is not likely either.

#define pHardwareRegName reinterpret_cast<volatile int*>(0x11223344)
//later in code
hardwareRegName = *pHardwareRegName; //remember hardwareRegName is not volatile
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Well but there are libraries where you need to use reinterpret_cast to interface with their apis. I have worked on porting some netsnmp code from C to C++ and I had to do this weird casting ` session.community = reinterpret_cast <u_char *> (const_cast <char *> (this->GetCommunityGet().c_str())); ` without any alternative. So you must avoid as a good practice but you may be compelled to use it at times. –  enthusiasticgeek Aug 28 '12 at 16:31
@enthusiasticgeek: Yikes, that looks like a disaster waiting to happen. Why does session.community need a nonconst and are you sure that GetCommunityGet wont change/go out of scope/be invalid when using session.community? Cause that appears risky. I'd probably just make a copy (strdup(this->GetCommunityGet().c_str()) for my sanity –  acidzombie24 Aug 28 '12 at 16:49
well I have a reference counting smart pointer and allocate heap in the constructor initialization list although strdup would do fine. –  enthusiasticgeek Aug 28 '12 at 21:06
How would you go about refactoring stackoverflow.com/q/21753538/14250 away from a c-style cast, without using reinterpret_cast? –  deworde Feb 13 '14 at 11:55
@deworde: In C++ I'd make PostMessage a template that accepts anything as it's parameters. Or i'd make a virtual function called NEXTDLGCTL. Interacting with C requires you to use reinterpret. Occasionally libraries require you to do that too but usually it's pretty straightforward. In a pure sense if you're only using C++ you wouldn't need to use reinterpret_cast –  acidzombie24 Feb 13 '14 at 21:34

Read the FAQ! Holding C++ data in C can be risky.

In C++, a pointer to an object can be converted to void * without any casts. But it's not true the other way round. You'd need a static_cast to get the original pointer back.

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