These set of changes focus primarily on getting the core logic and overall Godot Editor UI and functionality up and running natively on Android devices.
UI tweaks / cleanup / polish, as well configuration for Android specific functionality / restrictions will be addressed in follow-up PRs iteratively based on feedback.
Co-authored-by: thebestnom <shoval.arad@gmail.com>
Since some porjects may be relying on the former behavior, this is opt-in via a new project setting, disabled by default, but enabled for new projects, since it's the new standard behavior (and the only one in 4.0).
Using codespell 2.2-dev from current git.
Added `misc/scripts/codespell.sh` to make it easier to run it once in a
while and update the skip and ignore lists.
(cherry picked from commit 1bdb82c64e)
- Add a range hint to the Viewport `shadow_atlas_size` property.
- Add range steps to the shadow resolution project settings that
match the lowest allowed values (since lower increments don't
make sense).
having the raycast distance hardcoded to `10000` caused input events
to not be registered in very large 3D scenes.
This resolves the issue by using the cameras far distance instead.
Creating the more predictable behavior of if an object is visible,
it will be picked by the viewport.
resolves: #49735
(cherry picked from commit 02b6bbc5df)
Sets `AlignOperands` to `DontAlign`.
`clang-format` developers seem to mostly care about space-based indentation and
every other version of clang-format breaks the bad mismatch of tabs and spaces
that it seems to use for operand alignment. So it's better without, so that it
respects our two-tabs `ContinuationIndentWidth`.
This is only available on the GLES3 backend.
This can be useful for advanced shaders, but it should generally
not be enabled otherwise as full precision has a performance cost.
For general-purpose rendering, the built-in debanding filter should
be used to reduce banding instead.
This is an older, easier to implement variant of CAS as a pure
fragment shader. It doesn't support upscaling, but we won't make
use of it (at least for now).
The sharpening intensity can be adjusted on a per-Viewport basis.
For the root viewport, it can be adjusted in the Project Settings.
Since `textureLodOffset()` isn't available in GLES2, there is no
way to support contrast-adaptive sharpening in GLES2.
This fixes a bug where users of the scrollbar had to be very careful
not to move the mouse outside the viewport, otherwise the scrollbar
would drop its drag-action and stop scrolling until clicked again.
The existing behaviour had the side-effect of also dropping the
cosmetic highlighting of the scrollbar (in addition to the dragging),
for the specific case where the mouse was move outside the window.
The previous behaviour did nothing to remove the highlight if the
mouse was released (but not moved) inside the viewport.
This separate issue with the lingering highlight of the scrollbar
(until a mouse-movement action is performed inside the viewport) is
fixed in an immediate followup to this commit.
Closes bug #39634
(cherry picked from commit 44657db3e2)
Setting each point's position was missing for 3D. Now enabling collision
render debug will display contact points for 3D physics, the same way it
does for 2D physics.
Note: Multimesh rendering seems not to work in this scenario on master,
but it's working fine on 3.2.
(cherry picked from commit e5e9be8355)
This adds a new project setting (`physics/common/enable_pause_aware_picking`). It's disabled by default.
When enabled, it changes the way 2D & 3D physics picking behaves in relation to pause:
- When pause is set, every collision object that is hovered or captured (3D only) is released from that condition, getting the relevant mouse-exit callback., unless its pause mode makes it immune from pause.
- During the pause. picking only considers collision objects immune from pause, sending input events and enter/exit callbacks to them as expected.
- When pause is left, nothing happens. This is a big difference with the classic behavior, which at this point would process all the input events that have been queued against the current state of the 2D/3D world (in other words, checking them against the current position of the objects instead of those at the time of the events).