When downscaling more than 2x in either dimension, force mipmap use for
the texture in a texture node.
It improves the quality of textures but takes extra work.
The GL renderer does this, too (for textures that aren't in the icon cache).
This can be disabled via GSK_GPU_SKIP=mipmap.
Fixes the big-checkerboard-scaled-down2 test.
Unless GSK_GPU_SKIP=gradients is given, we sample every point 4x instead
of 1x. That makes the shader run slower (by roughly a factor of 2.5x)
but it improves quality quite a bit.
I'm a bit unsure about using the zero rect in the fallback situtation
where one image doesn't exist, but it seems to work.
This removes the last pattern-only rendernode and with that the last
fallback usage with disabled ubershader.
This way we can toggle opacity handling on/off.
THe shader slowly turns into a fancy texture op - but I don't want to
rename it to "fancytexture" just yet.
A variation is a #define/specialization constant that every shader can
use to specialize itself as it sees fit.
This commit adds the infrastrcture, future commits will add
implementations.
gdk_texture_save_to_png_bytes() cannot fail, so ensure that it doesn't.
Testsuite has been updated to check for this case.
Note that we do not load the PNG file that we generate here.
Loading is a lot more scary than saving after all.
If people want to load oversized PNG files, they should use a real PNG
loader.
If we enter the situation where we need to redirect the clipping to an
offscreen, make sure that:
* the ubershader gets only used when beneficial
* we size the offscreen properly and don't let it grow infinitely.
Fixes the clip-intersection-fail-opacity test
There are various places where the alpha is implicitly assumed to be
handled, so just handle it.
As a bonus, this simplifies a bunch of code and makes the texture node
rendering work with alpha.
Use an offscreen and mask it if the clips get too complicated.
Technically, the code could be improved to set the rounded clip on the
offscreen instead of rendering it as a mask, but that would require more
sophisticated tracking of clip regions by respecting the scissor, and
the current clip handling can't do that yet.
This removes one of the last places where the GPU renderer was still
using Cairo fallbacks.
This is for generating descriptors for more than 1 image. The arguments
for this function are very awkward, but I couldn't come up with better
ones and the function isn't that important.
And the calling places still look a lot nicer now.
For now this uses Cairo to generate a mask and then runs a mask op.
This is different from just using fallback in that the child is rendered
with the GPU and not via fallback.
A generic part that can be shared by all gradient shaders that does the
color stop handling and a gradient-specific part that needs to be
implemented individually by each gradient implementation.
If there are more than 7 color stops, we can split the gradient into
multiple gradients with color stops like so:
0, 1, 2, 3, 4, 5, transparent
transparent, 6, 7, 8, 9, 10, transparent
...
transparent, n-2, n-1, n
and use the new BLEND_ADD to draw them on top of each other.
Adapt the testcae that tests this to use colors that work with the fancy
algorithm we use now, so that BLEND_ADD and transitions to transparent
do not cause issues.
Instead of scaled coordinates, use the unscaled ones.
This ensure that gradients get computed correctly as they are not safe
against nonorthogonal transforms - like scales with different scale
factors.
The shader can only deal with up to 7 color stops - but that's good
enough for the real world.
Plus, we have the uber shader.
And if that fails, we can still fall back to Cairo.
The code also doesn't handle repeating linear gradients yet.
This shader can take over from the ubershader. And it can be used
instead of launching the ubershader when no offscreens are necessary.
Also includes an optimization that uses the colorize shader when
appropriate.
The ubershader has some corner cases where it can't be used, in
particular when the child is massively larger than the repeat node and
the repeat node is used to clip lots of the source.
It's better than the Cairo renderer, so use it instead.
It's still only picked once GL fails, so it will probably only ever be
picked when people use GDK_DEBUG=gl-disable, but at least it will be
picked.
per-backend renderers and GL renderers are a different thing, so treat
them as such.
Also, try the GL renderer unconditionally. The renderer initialization
code will take care of GL not being available.
This is using the Vulkan renderer.
It also allows claiming support for all the formats that only Vulkan
supports, but that neither GL nor native mmap can handle.
Add GSK_GPU_IMAGE_RENDERABLE and GSK_GPU_IMAGE_FILTERABLE and make sure
to check formats for this feature.
This requires reorganizing code to actually do this work instead of just
pretending formats are supported.
This fixes GLES upload tests with NGL.
I did it because it unifies the code.
But it also gains the benefit of being debuggable because it can
now be turned off via GDK_VULKAN_SKIP=incremental-present
This ensures both that we signal a semaphore for a dmabuf when we export
an image and that we import semaphores for dmabufs and wait on them.
Fixes Vulkan node-editor displaying the Vulkan renderer in the sidebar.
Make gsk_renderer_render_texture() create a dmabuf texture if that is
possible.
If it isn't (ie if we're not on Linux or if dmabufs are otherwise not
working) fall back to the previous code of creating a memory texture.