MozReview-Commit-ID: A1lCqvbQYAF
There is no clean API-based solution to this, so instead I went grovelling
through the DCOM wire protocol and was able to write a function that converts
handler OBJREFs into standard OBJREFs.
See also:
https://msdn.microsoft.com/en-us/library/cc226801
--HG--
extra : rebase_source : a650055c4adda3a1d99262e47f2b463074c6b935
MozReview-Commit-ID: LVML7EZaSYD
In non-e10s AccessibleWrap::HandleAccEvent, we special case our handling of
CARET_MOVED and FOCUS events with a call to UpdateSystemCaretFor. In e10s mode
we were not doing the same thing for proxied events sent from content. This
threw JAWS for a loop and presumably messes up other ATs as well.
This patch modifies the IPDL messages for these two events so that we may
send the caret rect along with the event, thus allowing us to update the
system caret for proxied events as well.
--HG--
extra : rebase_source : e1502c12b038739520afd5c7078d011e25ea669e
Here is a scenario under which the assert is invalid:
RecvHideEvent is received on a DocAccessibleParent DAP1 that has a child document DAP2... that in turn has a child document DAP3. DAP1::RecvHideEvent calls Shutdown on its root ProxyAccessible. This recursively calls Shutdown on child ProxyAccessibles until it reaches the one that is the parent of the child document DAP2. ProxyAccessibleBase::Shutdown then attempts to Unbind DAP2, which calls DAP1::RemoveChildDoc, which trips the assert because DAP2 has child document DAP3.
We sometimes briefly have more than one root DocAccessible associated with a TabChild, for example, while navigating links in a page. This patch makes sure that we use the correct accessible when delaying messages that we forward to the parent process.
MozReview-Commit-ID: Kp8x5o66nrY
I want AccessibleHandler.dll to use different UUIDs based on release channel.
The way I was doing it before wasn't working correctly because I also wanted
local builds to have their own set of UUIDs vs our regular Nightly/Beta/Release
builds.
I also want the beta channel to have its own set of UUIDs that are distinct
from release.
I'm using MOZ_UPDATE_CHANNEL to distinguish between the channels when
NIGHTLY_BUILD and BETA_OR_RELEASE are insufficient.
--HG--
extra : rebase_source : 8cb28a22a3cac16fb743a8fe81db5e120c1fdf6d
We need to update mChildDocs on child document removal. This also cleans up some code related to setting a new child doc when one is already set -- we now assert that this cannot happen.
MozReview-Commit-ID: HkiIgDQURtK
The a11y COM handler consists of two classes. AccessibleHandler is the one that
is actually interposed by COM between the client and the proxy. It implements
IAccessible2_3, IServiceProvider, and IProvideClassInfo. It is derived from
mscom::Handler which takes care of most of the COM boilerplate for handler
instantiation. AccessibleHandler must override a few virtual functions from
mscom::Handler:
* QueryHandlerInterface - mscom::Handler must implement the "real" QI. This is
the method that mscom::Handler uses to delegate to the implementer.
* ReadHandlerPayload - deserializing the payload. This uses
mscom::StructFromStream and the IA2Data_Decode function that was generated by
midl. It should essentially be the inverse of the serialization code in the
IHandlerProvider implementation inside Gecko.
* MarshalAs - identical to IHandlerProvider::MarshalAs
* GetHandlerPayloadSize and WriteHandlerPayload - it sucks that we have to
include these, but they are neccessary for the scenario when COM wants to
make a proxy of a proxy. When that happens, we need to get COM to serialize
the payload again; it isn't smart enough to recognize payloads in existing
proxies and copy them itself.
In order to reduce round trips, AccessibleHandler implements the most
sophisticated IA2 interface. This way the client has access to any of those
interfaces from IDispatch all the way down to IAccessible2_3 without needing to
incur additional round-trips to obtain them.
We also implement IServiceProvider so that a client may QueryService for an IA2
interface without needing to incur more round trips. In addition, we maintain
a list of service IDs that we definitely do not support, and handle those
locally instead of incurring an IPC round-trip.
We also implement IProvideClassInfo because NVDA's python code (and presumably
other ATs that use interpreted languages) supports using that interface to
assist its FFI library with resolution of our COM objects.
COM wraps each instance of an IAccessible* proxy with an AccessibleHandler
object. Proxies whose interfaces are not part of the IDispatch ... IAccessible2_3
hierarchy are not wrapped with handlers (though this might change in the future
if we need to expand coverage). AccessibleHandler implements IAccessible2_3 such
that, if we have cached data available for a particular IA2 method, we provide
that cached data to the client. Otherwise we pass on the request to the COM
proxy for retrieval via IPC.
The other class in the handler dll is AccessibleHandlerControl. This class
implements the IHandlerControl interface that is provided to IGeckoBackChannel.
Gecko dispatches cache invalidation events using this interface. This class
is a singleton within the handler dll and manages shared, handler-wide resources.
--HG--
extra : rebase_source : 4fc3910f789b0ed92c90655344ffb89f576ca5bd
MozReview-Commit-ID: GTQF3x1pBtX
A general outline of the COM handler (a.k.a. the "smart proxy"):
COM handlers are pieces of code that are loaded by the COM runtime along with
a proxy and are layered above that proxy. This enables the COM handler to
interpose itself between the caller and the proxy, thus providing the
opportunity for the handler to manipulate an interface's method calls before
those calls reach the proxy.
Handlers are regular COM components that live in DLLs and are declared in the
Windows registry. In order to allow for the specifying of a handler (and an
optional payload to be sent with the proxy), the mscom library allows its
clients to specify an implementation of the IHandlerProvider interface.
IHandlerProvider consists of 5 functions:
* GetHandler returns the CLSID of the component that should be loaded into
the COM client's process. If GetHandler returns a failure code, then no
handler is loaded.
* GetHandlerPayloadSize and WriteHandlerPayload are for obtaining the payload
data. These calls are made on a background thread but need to do their work
on the main thread. We declare the payload struct in IDL. MIDL generates two
functions, IA2Payload_Encode and IA2Payload_Decode, which are used by
mscom::StructToStream to read and write that struct to and from buffers.
* The a11y payload struct also includes an interface, IGeckoBackChannel, that
allows the handler to communicate directly with Gecko. IGeckoBackChannel
currently provides two methods: one to allow the handler to request fresh
cache information, and the other to provide Gecko with its IHandlerControl
interface.
* MarshalAs accepts an IID that specifies the interface that is about to be
proxied. We may want to send a more sophisticated proxy than the one that
is requested. The desired IID is returned by this function. In the case of
a11y interfaces, we should always return IAccessible2_3 if we are asked for
one of its parent interfaces. This allows us to eliminate round trips to
resolve more sophisticated interfaces later on.
* NewInstance, which is needed to ensure that all descendent proxies are also
imbued with the same handler code.
The main focus of this patch is as follows:
1. Provide an implementation of the IHandlerProvider interface;
2. Populate the handler payload (ie, the cache) with data;
3. Modify CreateHolderFromAccessible to specify the HandlerPayload object;
4. Receive the IHandlerControl interface from the handler DLL and move it
into the chrome process.
Some more information about IHandlerControl:
There is one IHandlerControl per handler DLL instance. It is the interface that
we call in Gecko when we need to dispatch an event to the handler. In order to
ensure that events are dispatched in the correct order, we need to dispatch
those events from the chrome main thread so that they occur in sequential order
with calls to NotifyWinEvent.
--HG--
extra : rebase_source : acb44dead7cc5488424720e1bf58862b7b30374f
The Manager is set by IPDL for remotely constructed objects but our DocAccessibleChilds are created on the child process side, so we need to assign a manager in the constructor so that we can find it when needed.
--HG--
extra : rebase_source : 8bf76534860ed73fbdc71df494130f6028400fa3
a BindChildDoc message can race with the parent process shutting down a tab.
The result of that is that RecvBindChildDoc() can be called on a
DocAccessibleParent that has already been shut down by the destruction of the
owning TabParent.
sending the emulated window information is basically unrelated to sending the
parent COM proxy to the child process, and in the future it will be useful to
send these at different times.