* avm2: Implement `BitmapData.draw` for `wgpu` backend
This method requires us to have the ability to render directly to a
texture. Fortunately, the `wgpu` backend already supports this in
the form of `TextureTarget`. However, the rendering code required
some refactoring in order to avoid creating duplicate `wgpu` resources.
The current implementation blocks on copying the pixels back
from the GPU to the CPU, so that we can immediately set them in
the Ruffle `BitmapData`. This is likely very inefficient, but will
work for a first implementation.
In the future, we could explore allowing the CPU image data and GPU
texture to be out of sync, and only synchronized when explicitly
necessary (e.g. on `getPixel` or `setPixel` calls).
* Rename `with_offscreen_backend` to `render_offscreen` and use Bitmap
* Don't panic when backend doesn't implement `render_offscreen`
The stub implementation was breaking code that relied on being
able to set a value for 'mask' and then retrieve it
(which used to work on a dynamic class like `MovieClip`).
Fixes some issues with our winding # calculation which would cause
incorrect results for hitTest.
* The convention for handling an intersection at endpoints was
not the same between lines and bezier curves.
* The bezier curve winding # function was not properly handling
some cases where the curve was strictly y-monotonic.
* Simplify the code a bit so that ray-curve intersections are
returned in a consistent order based on upward/downward crossing.
For now, I've left 'dropTarget' unimplemented - unlike in
AVM1, the drop target can be non-interactive objects like `Shape`,
so we'll need additional refactoring to implement it.
This allows 'This is the only level too' to be playable
This brings us closer to matching the Flash Player
enumeration behavior. Unfortunately, the precise enumeration
order for ScriptObject properties depends on the precise
order in the internal avmplus hashmap. This order is deterministic,
but adding/removing a property effectively randomizes it. Hopefully
there aren't any SWFS that depend on the *exact* order.
We previously used 'coerce_to_object', which produced
an error with `Value::Null`. Instead, we can just ues
`value.as_type_of`, which will correctly handle `null`
The test output for this test is sensitive to where we cut off each frame, because it doesn't stop all of it's handlers at the end of the test. Flash Player will just print lines forever so the end of the test is entirely arbitrary.
Reverts #7267
The image tests for the upcoming 'DisplayObject.stageRect' support
differ between Linux and Windows, so we need this support again.
To avoid the Linux filename churn that we previously encountered,
we now only include the platform and graphics backend in the filename
(e.g. `expected-linux-Vulkan`). This may result in some unexpected
'mismatched image' test failures if GHA updates to a version of Lavapipe
that changes rendering output, but this should be relatively easy to
notice.
This PR implements the `Loader.load` method, as well as
the associated `LoaderInfo` properties and events.
We can now load in an external AVM2 SWf: it will be added
as a child of `Loader` object, and will render properly
to the screen.
Limitations:
* The only supported `URLRequest` property is `url`
* `LoaderContext` is not supported at all - we always use the default
behavior
* Only `Loader.load` is implemented - we do not yet support unloading.
* We fire a plain 'Event' for the 'progress' event, instead of using
the (not yet implemented) 'ProgressEvent' class
The main changes in this PR are:
* The AVM2 `Loader` class now has an associated display object,
`LoaderDisplay`. This is basically a stub, and just renders
its single child (if it exists).
* `LoaderStream::Stage` is renamed to `LoaderStream::NotYetLoaded`.
This is used for both the `Stage` and an 'uninitialized'
`Loader.contentLoaderInfo`. In both cases, certain properties throw
errors, while others return actual values.
* The rust `Loader` manager now handles both AVM1 and AVM2 movie loads.
Previously, the viewport height and width were stored in
both `Stage` and the `RenderBackend`. Any changes to the viewport
dimensions (e.g. due to window resizing) needed to be updated in both
places to keep our handling of the viewport consistent.
This PR adds a new `ViewportDimensions` type, which holds the
width, height, and scale factor. It is stored inside the
`RenderBackend` impl, and is retrieved using the newly added
method `RenderBackend.get_viewport_dimensions`. After a `Player`
has been constructed, any code that needes access to the viewport
dimensions will ultimate go through this method.
Unfortunately, `Stage` needs to use the viewport dimensions
in `build_matrices`. Therefore, any code modifying the viewport
dimensions should go through `player.set_viewport_dimensions`,
which ensures that the stage matrices are rebuilt after the render
backend is updated.