This doesn't perfectly match Flash's behavior - I haven't been
able to reproduce the values produces when the DisplayObject
starts out with certain 'Matrix' values (a non-zero 'b' or 'd').
Howver, when the 'b' and 'd' matrix values are both 0, setting
'dobj.rotation = NaN' has no effect on the matrix, while
'dobj.scaleX = NaN' and 'dobj.scaleY = NaN' both treat 'NaN'
as 0 for the purposes of updating the matrix.
This fixes the tack shooter in Bloons Tower Defense 3, which
tries to set 'rotation = NaN' for spawned tacks.
This is necessary to make Steambirds get past the preloader screen.
All of the previous tests continue to pass with this change.
This commit modifies the existing test to start from within
the symbol_class constructor, instead of a frame script. In
this situation, a freshly-created orphan with a framescript will
run directly after the constructor returns, *before* an enterFrame
handler for the same orphan. I've verified that this modified test
fails without my change.
It's possible to call 'start()' on a timer
that has currentCount >= repeatCount. This will
cause the timer to tick exactly once, and then stop agian.
We were incorrectly reporting 'timer.running' in such a scenario:
'running' should be reported as 'true' up until just before the
'TimerEvent.TIMER_COMPLETE' is fired.
This fixes gaining money from bloon popping / level completion
in BTD5.
Depending on when loading completes, calling
`catchup_display_object_to_frame` might trigger an
`addedToStageEvent` inside the loaded SWF. The event listener
will expect the SWF content to have 'DisplayObject.stage' accessible,
so we need to make sure that we've added our loaded content as
a child of the `Loader` *before* any event handlers run.
I've been unable to come up with a self-contained test for this,
but it's necessary for Bloons Tower Defense 5
Previously, the Vector$ classes were only exported in the internal 'AS3.vec' namespace, which is used by older ActionScript code. However, newer ActionScript code can also access these classes through the public 'AS3.vec' namespace, via 'getDefintionByName'.
We now export these classes in both namespaces. In the public 'AS3.vec' namespace, they are exported like 'Vector.' instead of 'Vector$uint'
We still want to propagate these hits to the parent, which may
be able to handle them. My existing tests missed this case,
since all of the parent objects had content which was
behind the child content. When the only clickable content
comes from a child with 'mouseEnabled=false', we should
still fire an event targeting the parent (when applicable
based on the parent's flags).
This fixes dragging on the background (without any scenery present)
in Steambirds.
When a MovieClip is an 'orphan' (it has no parent),
it still has frames run (including frame scripts). Some SWFS
like SteamBirds and 'This is the Only Level TOO' rely on this behavior,
so we need to implement it.
The overall idea is straightforward - we keep a global list of
orphan movies, which we add to whenever we unset the parent for a movie.
This list stores weak references for consistency with Flash.
When we run a frame, we process entries in the root movie list,
in addition to the normal recursive processing from the `Stage`.
However, exactly matching Flash's output turned out to be quite tricky.
The particular sequence of calls I make in `run_all_phases_avm2` makes Ruffle
pass two complicated test cases, but there could still be lurking bugs.
This is enough to get SteamBirds to the first level (which doesn't
render due to a different error).
We were previously performing a redundant 'self.hit_test_shape'
call in 'avm2_mouse_pick'. All of the logic in that function
is handled in `avm2_mouse_pick.` Additionally, this call happened
before we tested out children, which would result in us targeting
a parent's drawing instead of aa child.
Surprisingly, Flash allows mutliple classes in an inheritance chain
to hav a linked `class_symbol`. When we instantiate a `DisplayObject`,
we need to stop at the first such `class_symbol` we find. This means
that any fields set from named children will *only* be set in the
first class we find, not in any of the parent classes (as their
corresponding library symbol will not be instantiated).
Previously, we would continue looping even after we found a
`class_symbol`, resulting in the furthest ancestor *winning*
the `set_object2` call.
This is a very large diff, but most of it comes from test files and
output.
This PR ads partial support for the following Stage3D shader features:
* Normal (square), rectangle, and cube textures
* Varying and temporary registers
* Lots of opcodes
The combination of these allows us to get a raytracing program
fully working in Ruffle. I've included it as image test.
Currently, this test is very slow (about 90 seconds on my machine),
as the code I'm using (https://github.com/saharan/OGSL) includes
its own shader language and compiler. THe raytracing demo
first compiles its own shader language to AGAL, and then starts
rendering the scene.
Limitations:
* Many opcodes are still unimplemented
* Most non-default texture options (e.g. mipmaps) are not implemented
We were previously calling `get_property` to determine if a `toJSON`
property exists, but that produces an error if the method is missing
on a sealed class.
Additionally, JSON serialization wasn't taking into account properties
from the vtable. All public properties (including fields, const fields,
and getter methods) get serialized.
Unfortunately, our vtable property order currently doesn't match
Flash's. I've hand-edited the test output for now (all of the actual
properties are there, just in a different order), and added a note
This includes all of the XML elements described in 'describeType' docs.
Unfortunately, the order of elements produced by Flash depends on
the iteration order of internal hashtables. As a result, the test
manually stringifies an XML object, sorting the stringified children,
to produce consistent output between Flash and Ruffle.
This requires the ability to do a limited 'set_property',
as well as `get_enumerant_value`.
To prevent modification of XMLLists derived from queries,
I've introduced a `target` field on `XMLList`. This is
`None` for lists created with `new XMLList()`, and `Some`
when the list was derived from a query on an existing `XML`
/`XMLList`. We only allow `set_property` when `target` is `None`:
this is enough for filtering to work, and prevents silent incorrect
execution when trying to modify an existing node.
Previously there were multiple implementations scattered across the
codebase. Unify them to a single place, in a more "Rusty" way (now
it's called via dot notation, rather than as a free function).
This makes Vector consistenht with the other implementations
of `get_enumerant_name`. This also fixes a bug where AMF object
serialization would loop all te way to `u32::MAX` when serializing
a vector, because it would never see `Value::Undefined` and break.
The Adobe Animate compiler can emit a 'newclass' opcode for
a concrete class before the 'newclass' opcodes for the interfaces
it implements. As a result, we cannot rely on looking up an interface
`ClassObject` when resolving a class's interfaces.
We now store a map of exported classes in `Domain`, and use this
to lookup interfaces before their `ClassObject`s have been created.
Additionally, `link_interfaces` was failing to consider superinterfaces,
which meant that methods from superinterfaces were not being copied
into the vtable. I've fixed this along with the other changes.
The mouse picking behavior in AVM2 interacts in complicated
ways with `mouseEnabled` and `mouseChildren.` It's sufficiently
different from AVM1 that I decided to split the logic into separate
`mouse_pick_avm1` and `mouse_pick_avm2` methods.
The `mouseChildren` property is now fully implemented.
Additionally, the `click_block` tests now work correctly
under Ruffle.
Combined with the orphan-movie PR, this is enough to make
SteamBirds fully playable (though performance greatly degrades
over a course of a level).
Since `initial_data` was removed from `Character::Bitmap` in #9143,
it now holds a single field. Move back to an unnamed field, which
aligns with the other `Character` enum variants.
These getters were previously calling `local_to_global`
with the unused localX/localY coordinate set to 0. Howver,
`local_to_global` does a matrix multiplication, which in general
will depend on both the x and y values. This was causing the getters
to return incorrect results when any of the `transform.matrix` values
included a non-diagonal matrix.
We now call `local_to_transform` with the real `localX` and `localY`
values.
The Newgrounds API checks `Security.sandboxType` to see if it should
run in debug mode or not (which determines whether or not medals
can actually be unlocked).
For now, desktop continues to use `localTrusted` as the default,
while web now uses `remote`. We might want to make this configurable
at some point, but this should be good enough for now (and better
match Flash's behavior).
Flash supports calling `Sound.play`, `SoundChannel.stop`, and
`SoundChannel.soundTransform` while a sound load is in progress
(e.g. immediately after calling `Sound.load`).
To support this, we queue up information inside `SoundObject`
and `SoundChannelObject` when a load is in progress. When a load
completes, we trigger any queued `Sound.play` and `SoundChannel.stop`
calls, and apply the most recent `SoundChannel.soundTransform`
If we're going to overwrite the CPU pixels with the result of a
GPU operation, make sure the GPU texture is up to date with the
latest CPU pixels. I've also renamed the method to
`overwrite_cpu_pixels_from_gpu` to better reflect how it should
be used.
This is needed by the Newgrounds API. We don't have the ability
to make fake requests to HTTP urls in our test frameworks,
so I haven't added any tests for this. However, I tested locally
that this allows the Newgrounds API to work (and got a medal
in Cloud Wars).
When removing a clip, first check if it has an unload event listener somewhere
it's hierarchy.
If it does, enqueue the removal to happen on the next frame, by moving it to a negative depth.
* Take two: Delay reading image back from render backend using `SyncHandle`
This allows us to avoid blocking immediately after a `BitmapData.draw` call.
Instead, we only attempt to use the `SyncHandle` when performing an operation
that requires the CPU-side pixels (e.g. BitmapData.getPixel or BitmapData.setPixel).
In the best case, the SWF will never explicitly access the pixels of
the target BitmapData, removing the need to ever copy back the render backend
image to our BitmapData. If the SWF doesn't require access to the pixels immediately,
we can delay copying the pixels until they're actually needed, hopefully allowing
the render backend to finish processing the BitmapData.draw operation in
the backenground before we need the result.
Now that the CPU and GPU pixels can be intentionally out of sync with
each other, we need to ensure that we don't accidentally expose 'stale'
CPU-side pixels to ActionScript (which needs to remain unaware of
our internal laziness). We now use a wrapper type `BitmapDataWrapper`
to enforce that the `SyncHandle` is consumed before accessing the
underlying `BitmapData.
* core: Skip GPU->CPU sync for source and target BitmapData during draw
* Introduce DirtyState enum
This change makes it so that if there is a goto to a specific frame,
then a frame script is registered for that frame, and then a goto to the
same frame again, the frame script will not be skipped. At least one movie
appears to depend on this behaviour.
Now that a `Bitmap` always stores a `BitmapData`, we can read the pixels
directly from the `BitmapData`, instead of duplicating them in an
`initial_data` field
This makes `Bitmap` delegate to `BitmapData` for
all of the bitmap-related information (handle, width, and height).
As a result, we now unconditionally store a `BitmapData` in `Bitmap`.
As a result, swapping the underling `BitmapData` instance will
automatically change the properties (and rendered image) of a `Bitmap`.
This required some refactoring in the render backends in order to
get access to a `BitmapHandle` through `BitmapData`.
In future versions of `gc-arena`, the `Debug` impl. of `Gc`
and `GcCell` will print the pointed-to value, which will cause
derived `Debug` impls. to enter an infinite recursion.
As such, this manually implements `Debug` on types wrapping a
`Gc/GcCell` to maintain the current behavior.
Previous behaviour defaulted to undefined and applied the format to the
range [0,0) instead of defaulting to -1 and applying the format to the
full length of the TextField.
This code was always wrong; and only saved from breaking by other wrong code elsewhere. Specifically:
* `SimpleButton.construct_frame` sets the wrong initial state
* but `MovieClip.instantiate_child` fires frame events before `post_instantiation`
* and `SimpleButton.post_instantiation` sets the correct state
This works now because all object placement and removal happens in `enter_frame`. Constructing those objects right away causes them to drop added events.
We cannot remove other instances of `construct_frame`, however - those are in places where we actually do expect constructors to run, not just see things get placed.
This also centralizes all the code we added in the prior commit into `on_construction_complete`, which should be called whenever an AVM2 object finishes construction.
This has a few other knock-on effects:
* AVM2 added-to-timeline events are fired by each object after it constructs its AVM2 side. This is opposed to before when we fired them after object instantiation and placement. This also gets rid of a prior hack we had for the AVM2 root movie getting added to the stage - or, more accurately, adopts it for everything.
* The supercall constructor for `DisplayObject` runs `construct_frame` on all children. This matches Flash Player behavior.
NOTE: This currently breaks the `placed_with_name` check, so there's going to be a lot of spurious can't set warnings
Usage of TObject::as_script_object was always followed by an unwrap, and
only SuperObject returned None.
The name change is intended to make clearer the fact that using the
returned object may bypass special behavior.
* tests: Add a test for issue #8630
* core: No-op gotos in AS3 do not actually do anything, even though they emit events
Fixes issue #8630
* tests: Add more tests for various #8630-adjacent cases
* tests: Ignore the tests with script removal as they expect MovieClip children to be nulled upon removal
* chore: Case sensitive filesystem fix
Co-authored-by: Adrian Wielgosik <adrian.wielgosik@gmail.com>
`BitmapHandle` now holds `Arc<dyn BitmapHandleImpl>`.
This allows us to move all of the per-bitmap backend data into
`BitmapHandle`, instead of holding an id to a backend-specific
hashmap.
This fixes the memory leak issue with bitmaps. Once the AVM side of a
bitmap (`Bitmap`/`BitmapData`) gets garbage-collected, the
`BitmapHandle` will get dropped, freeing all of the GPU resources
assoicated with the bitmap.
This PR implements core 'stage3D' APIs. We are now able
to render at least two demos from the Context3D docs - a simple
triangle render, and a rotating cube.
Implemented in this PR:
* Stage3D access and Context3D creation
* IndexBuffer3D and VertexBuffer3D creation, uploading, and usage
* Program3D uploading and usage (via `naga-agal`)
* Context3D: configureBackBuffer, clear, drawTriangles, and present
Not yet implemented:
* Any 'dispose()' methods
* Depth and stencil buffers
* Context3D texture apis
* Scissor rectangle
General implementation strategy:
A new `Object` variant is added for each of the Stage3D objects
(VertexBuffer3D, Program3D, etc). This stores a handle to the
parent `Context3D`, and (depending on the object) a handle
to the underlying native resource, via `Rc<dyn
SomeRenderBackendTrait>`).
Calling methods on Context3D does not usually result in an immediate
call to a `wgpu` method. Instead, we queue up commands in our
`Context3D` instance, and execute them all on a call to `present`.
This avoids some nasty wgpu lifetime issues, and is very similar
to the approah we use for normal rendering.
The actual rendering happens on a `Texture`, with dimensions
determined by `createBackBuffer`. During 'Stage' rendering,
we render all of these Stage3D textures *behind* the normal
stage (but in front of the overall stage background color).