2015-03-20 06:32:43 -05:00
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** Understanding transitional VCL lifecycle **
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---------- How it used to look ----------
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All VCL classes were explicitly lifecycle managed; so you would
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do:
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Dialog aDialog(...); // old - on stack allocation
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aDialog.Execute(...);
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or:
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Dialog *pDialog = new Dialog(...); // old - manual heap allocation
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pDialog->Execute(...);
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delete pDialog;
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or:
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boost::shared_ptr<Dialog> xDialog(new pDialog()); // old
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xDialog->Execute(...);
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// depending who shared the ptr this would be freed sometime
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In several cases this lead to rather unpleasant code, when
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various shared_ptr wrappers were used, the lifecycle was far less than
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obvious. Where controls were wrapped by other ref-counted classes -
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such as UNO interfaces, which were also used by native Window
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pointers, the lifecycle became extremely opaque. In addition VCL had
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significant issues with re-enterancy and event emission - adding
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various means such as DogTags to try to detect destruction of a window
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between calls:
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ImplDelData aDogTag( this ); // 'orrible old code
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Show( true, SHOW_NOACTIVATE );
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if( !aDogTag.IsDead() ) // did 'this' go invalid yet ?
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Update();
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Unfortunately use of such protection is/was ad-hoc, and far
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from uniform, despite the prevelance of such potential problems.
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When a lifecycle problem was hit, typically it would take the
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form of accessing memory that had been freed, and contained garbage due
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to lingering pointers to freed objects.
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---------- Where we are now: ----------
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To fix this situation we now have a VclPtr - which is a smart
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reference-counting pointer (include/vcl/vclptr.hxx) which is
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designed to look and behave -very- much like a normal pointer
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to reduce code-thrash. VclPtr is used to wrap all OutputDevice
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derived classes thus:
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2015-03-30 11:49:20 -05:00
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VclPtr<Dialog> pDialog( new Dialog( ... ), SAL_NO_ACQUIRE );
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...
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pDialog.disposeAndClear();
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2015-03-20 06:32:43 -05:00
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However - while the VclPtr reference count controls the
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lifecycle of the Dialog object, it is necessary to be able to
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break reference count cycles. These are extremely common in
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widget hierarchies as each widget holds (smart) pointers to
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its parents and also its children.
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Thus - all previous 'delete' calls are replaced with 'dispose'
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method calls:
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** What is dispose ?
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Dispose is defined to be a method that releases all references
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that an object holds - thus allowing their underlying
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resources to be released. However - in this specific case it
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also releases all backing graphical resources. In practical
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terms, all destructor functionality has been moved into
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'dispose' methods, in order to provide a minimal initial
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behavioral change.
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2015-03-20 12:24:08 -05:00
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As such a VclPtr can have three states:
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VclPtr<PushButton> pButton;
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...
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assert (pButton == nullptr || !pButton); // null
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assert (pButton && !pButton->IsDisposed()); // alive
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assert (pButton && pButton->IsDisposed()); // disposed
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2015-03-20 06:32:43 -05:00
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** ScopedVclPtr - making disposes easier
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While replacing existing code with new, it can be a bit
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tiresome to have to manually add 'disposeAndClear()'
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calls to VclPtr<> instances.
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Luckily it is easy to avoid that with a ScopedVclPtr which
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does this for you when it goes out of scope.
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2015-03-30 11:49:20 -05:00
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** One extra gotcha - an initial reference-count of 1
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In the normal world of love and sanity, eg. creating UNO
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objects, the objects start with a ref-count of zero. Thus
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the first reference is always taken after construction by
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the surrounding smart pointer.
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Unfortunately, the existing VCL code is somewhat tortured,
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and does a lot of reference and de-reference action on the
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class -during- construction. This forces us to construct with
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a reference of 1 - and to hand that into the initial smart
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pointer with a SAL_NO_ACQUIRE.
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To make this easier, we have 'Instance' template wrappers
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that make this apparently easier, by constructing the
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pointer for you.
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2015-03-20 06:32:43 -05:00
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** How does my familiar code change ?
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Lets tweak the exemplary code above to fit the new model:
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2015-03-30 11:49:20 -05:00
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- Dialog aDialog(... dialog params ... );
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2015-03-20 06:32:43 -05:00
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- aDialog.Execute(...);
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2015-03-30 11:49:20 -05:00
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+ ScopedVclPtrInstance<Dialog> pDialog(... dialog params ... );
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2015-03-20 06:32:43 -05:00
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+ pDialog->Execute(...); // VclPtr behaves much like a pointer
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or:
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2015-03-30 11:49:20 -05:00
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- Dialog *pDialog = new Dialog(... dialog params ...);
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+ VclPtrInstance<Dialog> pDialog(... dialog params ...);
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2015-03-20 06:32:43 -05:00
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pDialog->Execute(...);
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- delete pDialog;
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+ pDialog.disposeAndClear(); // done manually - replaces a delete
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or:
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2015-03-30 11:49:20 -05:00
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- boost::shared_ptr<Dialog> xDialog(new Dialog(...));
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+ ScopedVclPtrInstance<Dialog> xDialog(...);
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2015-03-20 06:32:43 -05:00
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xDialog->Execute(...);
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+ // depending how shared_ptr was shared perhaps
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+ // someone else gets a VclPtr to xDialog
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or:
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- VirtualDevice aDev;
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2015-04-10 09:13:34 -05:00
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+ ScopedVclPtrInstance<VirtualDevice> pDev;
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2015-03-20 06:32:43 -05:00
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2015-04-16 04:50:26 -05:00
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Other things that are changed are these:
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- pButton = new PushButton(NULL);
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+ pButton = VclPtr<PushButton>::Create(nullptr);
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...
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- vcl::Window *pWindow = new PushButton(NULL);
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+ VclPtr<vcl::Window> pWindow;
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+ pWindow.reset(VclPtr<PushButton>::Create(nullptr));
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2015-03-20 06:32:43 -05:00
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** Why are these 'disposeOnce' calls in destructors ?
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This is an interim measure while we are migrating, such that
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it is possible to delete an object conventionally and ensure
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that its dispose method gets called. In the 'end' we would
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instead assert that a Window has been disposed in it's
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destructor, and elide these calls.
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As the object's vtable is altered as we go down the
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destruction process, and we want to call the correct dispose
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methods we need this disposeOnce(); call for the interim in
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every destructor. This is enforced by a clang plugin.
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The plus side of disposeOnce is that the mechanics behind it
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ensure that a dispose() method is only called a single time,
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simplifying their implementation.
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---------- Who owns & disposes what ? ----------
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** referencing / ownership inheritance / hierarchy.
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** VclBuilder
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+ and it's magic dispose method.
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---------- What remains to be done ? ----------
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2015-03-24 12:43:20 -05:00
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* Cleanup DogTags and LazyDelete.
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2015-03-20 06:32:43 -05:00
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* Expand the VclPtr pattern to many other less
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than safe VCL types.
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* create factory functions for VclPtr<> types and privatize
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their constructors.
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* Pass 'const VclPtr<> &' instead of pointers everywhere
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2015-03-23 04:14:13 -05:00
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+ add 'explicit' keywords to VclPtr constructors to
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accelerate compilation etc.
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2015-03-20 06:32:43 -05:00
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* Cleanup common existing methods such that they continue to
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work post-dispose.
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2015-03-23 04:14:13 -05:00
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* Dispose functions should be audited to:
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2015-03-20 06:32:43 -05:00
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+ not leave dangling pointsr
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+ shrink them - some work should incrementally
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migrate back to destructors.
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2015-04-16 04:50:26 -05:00
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* VclBuilder
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+ ideally should keep a reference to pointers assigned
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in 'get()' calls - to avoid needing explicit 'clear'
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code in destructors.
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2015-03-20 06:32:43 -05:00
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---------- FAQ / debugging hints ----------
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** Compile with dbgutil
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This is by far the best way to turn on debugging and
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assertions that help you find problems. In particular
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there are a few that are really helpful:
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vcl/source/window/window.cxx (Window::dispose)
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"Window ( N4sfx27sidebar20SidebarDockingWindowE (Properties))
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^^^ class name window title ^^^
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with live children destroyed: N4sfx27sidebar6TabBarE ()
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N4sfx27sidebar4DeckE () 10FixedImage ()"
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You can de-mangle these names if you can't read them thus:
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$ c++filt -t N4sfx27sidebar20SidebarDockingWindowE
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sfx2::sidebar::SidebarDockingWindow
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In the above case - it is clear that the children have not been
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disposed before their parents. As an aside, having a dispose chain
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separate from destructors allows us to emit real type names for
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parents here.
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To fix this, we will need to get the dispose ordering right,
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occasionally in the conversion we re-ordered destruction, or
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omitted a disposeAndClear() in a ::dispose() method.
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=> If you see this, check the order of disposeAndClear() in
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the sfx2::Sidebar::SidebarDockingWindow::dispose() method
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=> also worth git grepping for 'new sfx::sidebar::TabBar' to
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see where those children were added.
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2015-04-16 04:50:26 -05:00
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** Check what it used to do
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While a ton of effort has been put into ensuring that the new
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lifecycle code is the functional equivalent of the old code,
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the code was created by humans. If you identify an area where
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something asserts or crashes here are a few helpful heuristics:
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* Read the git log -u -- path/to/file.cxx
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=> Is the order of destruction different ?
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in the past many things were destructed (in reverse order of
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declaration in the class) without explicit code. Some of these
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may be important to do explicitly at the end of the destructor.
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eg. having a 'Idle' or 'Timer' as a member, may now need an
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explicit .Stop() and/or protection from running on a
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disposed Window in its callback.
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=> Is it 'clear' not 'disposeAndClear' ?
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sometimes we get this wrong. If the code previously used to
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use 'delete pFoo;' it should now read pFoo->disposeAndClear();
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Conversely if it didn't delete it, it should be 'clear()' it
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is by far the best to leave disposing to the VclBuilder where
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possible.
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In simple cases, if we allocate the widget with VclPtrInstance
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or VclPtr<Foo>::Create - then we need to disposeAndClear it too.
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