Currently, GeckoEditable periodically fires update composition events to
update the Gecko composition styling. To make the code more efficient
and more robust in dealing with content JS code, this patch merges these
events into events like replacing text, setting span, and removing span.
As a result, a setComposingText call now results in one replacing text
event instead of a replacing text event plus an update composition event.
Right now we call disposeNative on GeckoEditable in the
nsWindow::Natives destructor. However, we may still have pending native
calls in the event queue at that point, and these events will cause
exceptions when handled. This patch makes GeckoEditable call
disposeNative, after ensuring there's no pending calls.
This patch adds a separate close() call to nsWindow, and let the
GeckoView decide whether to make that call or not. This lets us use the
static version of disposeNative. If nsWindow is destroyed in the
meantime, we still want to call disposeNative, which would only be
possible using the static version of disposeNative.
The GeckoEditable instance doesn't change for each nsWindow instance.
However, because a GeckoInputConnection is associated with a GeckoView,
when we create a new GeckoView, we need to attach a new
GeckoInputConnection to the existing nsWindow's GeckoEditable. This
patch makes us do that inside nsWindow::Natives::Open by calling
GeckoEditable.OnViewChange.
This patch removes the GeckoEditable code in GeckoAppShell, and make
nsWindow create a GeckoEditable for itself when opening a window.
Instead of calling GeckoAppShell, nsWindow can now call GeckoEditable
methods directly.
We try to generate a C++ constant for static final fields, but that
was failing for inaccessible fields. Now we set the field to be
accessible so that we do end up generating a C++ constant.
The PROCESS_OBJECT GeckoEvent is used to set the layer client object in
Gecko once Gecko is done loading. This patch converts it to a native
call in GeckoView.Window.
GeckoView.Window is a class that acts as the interface between
GeckoView in Java and nsWindow in C++. It will contain native methods
that GeckoView will use to interact with nsWindow.
On initialization, Window.open is called to create a nsWindow and
establish the JNI association between Window and the native nsWindow.
Then, whenever Window instance methods are called, the JNI stubs will
automatically call members of nsWindow.
One thing we do in the Fennec CLH is to make a speculative connection
based on the URI that's passed in. However, by the time the CLH runs,
we're far along into startup, and the advantage of a speculative
connection is reduced. This patch implements making speculative
connection as a method in GeckoThread, so that Fennec can make a
speculative connection without relying on the Fennec CLH.
Many Gecko operations depend on the profile being available. This
patch adds a PROFILE_READY Gecko state so that we can queue calls
until profile is loaded.
First we need to set the Gecko thread JNIEnv* in nsAndroidStartup, but
after that we can initialize and deinitialize the rest of JNI, including
AndroidBridge, in GeckoAppShell. This makes nsAppShell control the
AndroidBridge lifetime. Over time, parts of the AndroidBridge
functionality will be migrated to nsAppShell.
This patch transforms RestrictedProfiles to delegate isAllowed() and
canLoadUrl() calls to an object implementing the RestrictionConfiguration
interface.
DefaultConfiguration, GuestProfileConfiguration and
RestrictedProfileConfiguration are implementing RestrictionConfiguration
and will take care of handling the restrictions for the different types
of profiles.
