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Language: C++ Toolkit: Qt4

The toolkit I'm using has a static method called int QEvent::registerEventType() to register my own event types. When I subclass this QEvent I need to supply the base class this value. QEvent::QEvent(int type).

Is it ok to use a static variable to call this before application starts? Consider the following:

//This is all in my .cpp file

static int myEventType;  //This will contain my registered type

/*If I create a static instance of this class the constructor 
  gets called before the main() function starts.
*/
class DoRegisterMyEventType {  
public:
  DoRegisterMyEventType() {
    myEventType = QEvent::registerEventType();
  }
};

static DoRegisterMyEventType doRegisterMyEventType;

//Here is the constructor for MyEvent class which inherits QEvent.
MyEvent::MyEvent()
  : QEvent(myEventType)
{
}

How 'evil' is this? I could wrap the whole thing in a namespace to prevent polluting the global namespace.

share|improve this question
    
Thinking about this I realize I could probably just call QEvent::registerEventType() in the constructor to my MyEvent object like so: MyEvent::MyEvent() : QEvent(QEvent::registerEventType()) { } and then provide the a method returning that type or something. – darkadept Feb 25 '10 at 20:42
    
I believe that only works if MyEvent is itself a singleton class, which isn't apparent from what you've already said. The point of storing the event ID (the int) separately is you can reliably pass the same value to the QEvent ctor from your MyEvent ctor every time. – Roger Pate Feb 26 '10 at 4:47
up vote 1 down vote accepted

Static level initialization is a huge compiler-dependent grey area, as others have mentioned. However, function level initialization is not a grey area and can be used to your advantage.

static inline int GetMyEventType()
{
    static int sEventType = QEvent::registerEventType();
    return sEventType;
}

MyEvent::MyEvent()
  : QEvent(GetMyEventType())
{
}

This solution has the property that registerEventType is guaranteed to be called before you need your event type even if you construct MyEvent during static initialization, which is good, but it does open you up to thread-safety issues if it's possible for MyEvent to be constructed on multiple threads.

Here's a thread-safe version, based on boost::call_once:

#include "boost/thread/once.hpp"

static boost::once_flag sHaveRegistered = BOOST_ONCE_INIT; //This is initialized statically, effectively at compile time.    
static int sEventType = -1; //-1 is not a valid event

static void DoRegister()
{
    sEventType = QEvent::registerEventType();
}

static inline int GetMyEventType()
{
    boost::call_once(sHaveRegistered, &DoRegister);
    return sEventType;
}
share|improve this answer
    
Note that this is effectively the same initialization technique as used by "Meyer's singleton" in Neil's answer, but does refactor the concerns in a better way. – Roger Pate Feb 26 '10 at 0:31
    
I totally agree that it's the same construct, but I also think it's a bit clearer than Neil's answer. It seems a little overly complex to have an entire class definition to store a single integer. It's also rather hard (though, not impossible) to make the class version thread-safe (which may or may not be a concern to the OP, but it tends to be a concern in my life). – Dan McCormick Feb 26 '10 at 0:40
    
Actually, the major difference is that Neil's answer would refactor the registry itself (QEvent) rather than uses of it, and I slightly prefer yours in that sense (and tried to say that in my comment). However, when you're talking about a single int and similar cases, I prefer my answer (of course :P), which boils down to the single line "int variable = some_func();" executed at the right time (consider how my answer is perfectly thread-safe, for example). The machinery to do that does get complex (but only needs setup once), and that machinery makes up the bulk of my answer. – Roger Pate Feb 26 '10 at 2:42
    
To clarify "perfectly thread-safe": the int might as well be const and immutable, as we can get the value at initialization, never need to change it, and multiple CPU cores can cache it however they like. Redefine the problem from "how to do thread-safe initialization" to "how to do initialization in the right order or at the right time". – Roger Pate Feb 26 '10 at 2:46

Since C++'s initialization across TUs is a big grey area with much implementation leeway, I prefer to scrap it completely and be explicit about what gets done when. (This rejection of initialization order due to lack of guarantees is similar to how singleton classes reject global objects.) Specifically, this means any global state (global variables, static data members, and function-local statics) that cannot be initialized with constant-expressions must be initialized in exactly one TU, and that TU is the one that implements main.

In the manual case, this means inserting and updating code in the translation unit that contains main and in main itself. The most common example of such code is calling srand(time(0)) to seed the std::rand PRNG.

You can refactor that manual code management using the preprocessor:

// the implementation file for main, could be named main.cpp

#include "whatever_declares_the_real_main.hpp"

#include "global_objects.inc"

int main(int argc, char* argv[]) try {
#include "main_init.inc"

  return the_real_main(argc, argv);

  // main.cpp has well-defined responsibility:
  // initialize global state before passing control to another function, and
  // handle return-code or exceptions

  // you can modify this, depending on your preference and desired API
  // for example:
  return the_real_main(std::vector<std::string>(argv+1, argv+argc));
  return the_real_main(parse_args(argv+1, argv+argc));
  // just make sure to keep main.cpp's responsibility well-defined and
  // relatively simple
}
// example handling; depending on your specifics, you might do something
// different, or know how to provide more information:
catch (std::exception& e) {
  std::cerr << "abnormal termination: " << e.what() << '\n';
  return 1;
}
catch (...) {
  std::cerr << "abnormal termination.\n";
  return 1;
}

These .inc files are neither headers nor implementation files. The exact file extension doesn't matter as long as you don't use something which is commonly used for headers or implementation files, such as .h, .hpp, .cc, .cpp, and so forth. You can generate global_objects.inc and main_init.inc based off file-naming conventions, using include guards so that dependencies may be included (just as include guards work for headers).

For example, both of these files correspond with myevent.hpp and would be placed alongside that header:

// file "myevent.global_inc"
#ifndef INCLUDE_GUARD_37E6F5857F8F47918A7C83F29A9DA868
#define INCLUDE_GUARD_37E6F5857F8F47918A7C83F29A9DA868

#include <QEvent.hpp> // or whatever headers you need

#include "myevent.hpp" // declares the variable defined just below
// (remember you use 'extern' to declare objects without defining them)

int your_namespace::myEventType = QEvent::registerEventType();

#endif

// file "myevent.main_inc"
#ifndef INCLUDE_GUARD_4F1B93D0F4D3402B802CBA433241AA81
#define INCLUDE_GUARD_4F1B93D0F4D3402B802CBA433241AA81

// nothing needed in this case, from what you've shown so far

// this is where you place expressions that would otherwise require a dummy
// global variable to make sure they are executed, but this also allows use
// of temporary variables while includes handle dependency order:
#include "something_else.main_inc" // fake example dependency, which must
{                                  // be executed first
  int temp;
  some_func(&temp);
  other_func(temp); // not easy to transform this into a global's init
  // expression, yet defining it this way is natural, because it's exactly
  // how you would do it inside a function
}

#endif

Note that if you only require static data initialization with constant-expressions, then that is preferred over all other techniques. The primary restriction for that initialization is not being able to make a function call (but it's actually more complex), so it doesn't apply in your case; this is the only kind of global variable initialization that C can do, if you want to find out more.

share|improve this answer

I use the "static register object" pattern quite a bit, but you must be aware of one big problem - you must ensure that the thing you are registering with, which itself is likely to be static, is created before the thing you are registering. As C++ does not guarantee the order of static construction between translation units, this can be problematic. One solution is to use the so called Meyer Singleton:

class Registry {
  public:
    static Registry & Instance() {
        static Registry r;
        return r;
    }

    ... 

 private:
    Registry() {    
      ...
    }
};

As all references to the Registry must go through the Instance() method, you are guaranteed the required construction order.

share|improve this answer
    
While decent advice, I don't think the OP has latitude to change QEvent this way. – Roger Pate Feb 25 '10 at 20:57
    
@Roger I guess - I don't use Qt myself. – anon Feb 25 '10 at 21:02
    
That's correct. I can't change the toolkit. Is there any way to ensure the static initialization order? – darkadept Feb 25 '10 at 21:08
    
Unfortunately you can't rely on any order of static initializations, except that they will all be done by the time main() is called. – Lars Feb 25 '10 at 21:15
    
@Lars That isn't true. There are several forms of static initialisation order you can depend on. I mentioned a couple in my answer. – anon Feb 25 '10 at 21:19

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