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IDE: Eclipse Juno; Compiler: MinGW 4.6.2; Project: Win32

I have a MainWindow with two somewhat-dissimilar MDI child windows: MdiChildWindowA and MdiChildWindowB. A third child window, SharedWindow, is not MDI but can be used by either MDI child window. All are encapsulated in their own C++ classes.

To avoid proliferation of SharedWindow, I borrowed part of the singleton design: MainWindowClass::GetSharedWindowInstance() will return a pointer to an instance of SharedWindow, creating one if one doesn't already exist. MainWindow.h includes SharedWindow* pSharedWindow to back up the function. (That's as close as SharedWindow gets to being a singleton.)

When MainWindow instantiates MdiChildWindowA and MdiChildWindowB, it passes this to their constructors, which they save in the class variable pMainWindow (defined as MainWindow* in MdiChildWindowA.h and MdiChildWindowB.h).

cout of this in MainWindow matches cout of pMainWindow in the MDI child window constructors, but by the time another function calls pMainWindow->GetSharedWindowInstance(), pMainWindow has changed! Making pMainWindow static seems to have solved the problem but how did pMainWindow change?

Similarly, I found that HMODULE and LPPICTURE variables had be static in SharedWindow.h or they would forget their values between functions in SharedWindow.cpp. Are pointer types somehow exempt from persistence as class variables? I thought static was meant to ensure one value across all instances of its class.

Edit 2013-Sep-04:
Below is my Application.cpp (largely copied from a tutorial). I thought my MainWindow instance was created on the heap and would persist until exiting.

#include "MainWindow.h"

int WINAPI WinMain( HINSTANCE hInstance, HINSTANCE hPrev, LPSTR lpCmdLine, int nCmdShow )
{   MSG  msg;
    HWND hMdiClientWindow;

    MainWindow *winMain = new MainWindow( hInstance );
    if( !winMain->Run( nCmdShow ) )
    {   delete winMain;
        return 1;
    }

    hMdiClientWindow = winMain->GetMdiClientWindow();

    while( GetMessage( &msg, NULL, 0, 0 ) )
    {   if( ! TranslateMDISysAccel( hMdiClientWindow, &msg ) )
        {   TranslateMessage( &msg );
            DispatchMessage ( &msg );
        }
    }

    delete winMain;

    return msg.wParam;
}

new MainWindow(...) invokes MainWindow::MainWindow(), where cout shows this is 0xdd13a0.

MainWindow is created in the call to Run(...), which passes the pointer to the instance of MainWindow in lpParam:

bool MainWindow::Run( int nCmdShow )
{   ...
    hMainWindow = CreateWindowEx( ..., this );
    ...
}

In the window procedure, the pointer is saved in the instance data of MainWindow:

LRESULT CALLBACK MainWindow::MainWindowProcedure( HWND hMainWindow, UINT Msg, WPARAM wParam, LPARAM lParam )
{   MainWindow* pThis;

    if( Msg == WM_NCCREATE )
    {   CREATESTRUCT* pCreateStruct = (CREATESTRUCT*) lParam;
        pThis = (MainWindow*) pCreateStruct->lpCreateParams;
        SetWindowLongPtr( hMainWindow, GWL_USERDATA, (LONG) pThis );
    } else
    {   pThis = (MainWindow*) GetWindowLongPtr( hMainWindow, GWL_USERDATA );
    }

In WM_CREATE, cout shows pThis is 0xdd13a0 when it's passed to the constructors of MdiChildWindowA and MdiChildWindowB:

switch( Msg )
{   ...
    case WM_CREATE:
    {   unique_ptr<MdiChildWindowA> upMdiChildWindowA;
        unique_ptr<MdiChildWindowB> upMdiChildWindowB;
        ...
        up_MdiChildWindowA = unique_ptr<MdiChildWindowA>( new MdiChildWindowA( m_hInstance, pThis, [window dimensions] ) );
        up_MdiChildWindowB = unique_ptr<MdiChildWindowB>( new MdiChildWindowB( m_hInstance, pThis, [window dimensions] ) );

The constructors of the MDI child windows copy the MainWindow pointer in the parameter pMainWindow into the class variable m_pMainWindow, and cout shows that both contain 0xdd13a0:

MdiChildWindowA::MdiChildWindowA( HINSTANCE hInstance, MainWindow* pMainWindow, ... )
{   m_pMainWindow = pMainWindow;
    ....
}

In WM_CREATE of the MDI child window procedure, cout shows m_pMainWindow still contains 0xdd13a0. The only other reference to m_pMainWindow occurs in WM_LBUTTONDBLCLICK where, unless I've made it static, it has somehow become 0xdd1380 (perhaps during a pass through DefMDIChildProc(...)?):

MdiChildWindowA::MdiChildWindowProcedure( ... )
{   ...
    switch( ... )
    {   ...
        case WM_LBUTTONDBLCLICK:
        {   SharedWindow* pSharedWindow;
            ...
            pSharedWindow = pThis->m_pMainWindow->GetInstanceOfSharedWindow();  // pThis points to this instance of MdiChildWindowA. cout confirms its value hasn't changed.

Since m_pMainWindow is pointing to the wrong place, the program crashes when a SharedWindow function is called via pSharedWindow. It appears however that GetInstanceOfSharedWindow() exists in this bogus instance of MainWindow because an address is returned - but, in the code above, it's the address of MdiChildWindowA!

(Note: my naming convention drives people nuts so I re-typed the code with less-dangerous names. Hopefully there are no typos.)

@brunocodutra, @Chris Hayes: I don't have enough points to comment yet, but I appreciate your ideas.

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3  
How has pMainWindow changed? It's most likely that you're causing a copy constructor to be invoked somewhere, so that you have identical objects at two different memory addresses. –  Chris Hayes Sep 4 '13 at 2:16

1 Answer 1

Hard to tell without the full relevant code, but I would guess MainWindow is being deallocated. I would further guess MainWindow is originaly stored in the stack, rather than the heap, because what causes the address to change is a function call (which alters the stack).

My advice: verify if either MainWindow or MdiChildWindowA and MdiChildWindowB (not sure which pMainWindow changes) are local variables and if so, change your code, so that they get allocated in the heap, i.e. dynamicaly through the use of the keyword new.

Answering the second question, pointers are not treated differently from any other type, in essence they are very much like integers, but their content is promptly allowed to be interpreted as memory addresses.

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