Add area sampling scaler to allow for super-sampled anti-aliasing. (#7304)

* Add area sampling scaler to allow for super-sampled anti-aliasing.

* Area scaling filter doesn't have a scaling level.

* Add further clarification to the tooltip on how to achieve supersampling.

* ShaderHelper: Merge the two CompileProgram functions.

* Convert tabs to spaces in area scaling shaders

* Fixup Vulkan and OpenGL project files.

* AreaScaling: Replace texture() by texelFetch() and use integer vectors.

No functional difference, but it cleans up the code a bit.

* AreaScaling: Delete unused sharpening level member.

Also rename _scale to _sharpeningLevel for clarity and consistency.

* AreaScaling: Delete unused scaleX/scaleY uniforms.

* AreaScaling: Force the alpha to 1 when storing the pixel.

* AreaScaling: Remove left-over sharpening buffer.
This commit is contained in:
ZenoArrows 2024-09-17 20:30:50 +02:00 committed by GitHub
parent cf77c011e4
commit f39e89ece7
No known key found for this signature in database
GPG Key ID: B5690EEEBB952194
15 changed files with 489 additions and 18 deletions

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@ -5,5 +5,6 @@ namespace Ryujinx.Graphics.GAL
Bilinear,
Nearest,
Fsr,
Area,
}
}

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@ -0,0 +1,106 @@
using OpenTK.Graphics.OpenGL;
using Ryujinx.Common;
using Ryujinx.Graphics.GAL;
using Ryujinx.Graphics.OpenGL.Image;
using System;
using static Ryujinx.Graphics.OpenGL.Effects.ShaderHelper;
namespace Ryujinx.Graphics.OpenGL.Effects
{
internal class AreaScalingFilter : IScalingFilter
{
private readonly OpenGLRenderer _renderer;
private int _inputUniform;
private int _outputUniform;
private int _srcX0Uniform;
private int _srcX1Uniform;
private int _srcY0Uniform;
private int _scalingShaderProgram;
private int _srcY1Uniform;
private int _dstX0Uniform;
private int _dstX1Uniform;
private int _dstY0Uniform;
private int _dstY1Uniform;
public float Level { get; set; }
public AreaScalingFilter(OpenGLRenderer renderer)
{
Initialize();
_renderer = renderer;
}
public void Dispose()
{
if (_scalingShaderProgram != 0)
{
GL.DeleteProgram(_scalingShaderProgram);
}
}
private void Initialize()
{
var scalingShader = EmbeddedResources.ReadAllText("Ryujinx.Graphics.OpenGL/Effects/Shaders/area_scaling.glsl");
_scalingShaderProgram = CompileProgram(scalingShader, ShaderType.ComputeShader);
_inputUniform = GL.GetUniformLocation(_scalingShaderProgram, "Source");
_outputUniform = GL.GetUniformLocation(_scalingShaderProgram, "imgOutput");
_srcX0Uniform = GL.GetUniformLocation(_scalingShaderProgram, "srcX0");
_srcX1Uniform = GL.GetUniformLocation(_scalingShaderProgram, "srcX1");
_srcY0Uniform = GL.GetUniformLocation(_scalingShaderProgram, "srcY0");
_srcY1Uniform = GL.GetUniformLocation(_scalingShaderProgram, "srcY1");
_dstX0Uniform = GL.GetUniformLocation(_scalingShaderProgram, "dstX0");
_dstX1Uniform = GL.GetUniformLocation(_scalingShaderProgram, "dstX1");
_dstY0Uniform = GL.GetUniformLocation(_scalingShaderProgram, "dstY0");
_dstY1Uniform = GL.GetUniformLocation(_scalingShaderProgram, "dstY1");
}
public void Run(
TextureView view,
TextureView destinationTexture,
int width,
int height,
Extents2D source,
Extents2D destination)
{
int previousProgram = GL.GetInteger(GetPName.CurrentProgram);
int previousUnit = GL.GetInteger(GetPName.ActiveTexture);
GL.ActiveTexture(TextureUnit.Texture0);
int previousTextureBinding = GL.GetInteger(GetPName.TextureBinding2D);
GL.BindImageTexture(0, destinationTexture.Handle, 0, false, 0, TextureAccess.ReadWrite, SizedInternalFormat.Rgba8);
int threadGroupWorkRegionDim = 16;
int dispatchX = (width + (threadGroupWorkRegionDim - 1)) / threadGroupWorkRegionDim;
int dispatchY = (height + (threadGroupWorkRegionDim - 1)) / threadGroupWorkRegionDim;
// Scaling pass
GL.UseProgram(_scalingShaderProgram);
view.Bind(0);
GL.Uniform1(_inputUniform, 0);
GL.Uniform1(_outputUniform, 0);
GL.Uniform1(_srcX0Uniform, (float)source.X1);
GL.Uniform1(_srcX1Uniform, (float)source.X2);
GL.Uniform1(_srcY0Uniform, (float)source.Y1);
GL.Uniform1(_srcY1Uniform, (float)source.Y2);
GL.Uniform1(_dstX0Uniform, (float)destination.X1);
GL.Uniform1(_dstX1Uniform, (float)destination.X2);
GL.Uniform1(_dstY0Uniform, (float)destination.Y1);
GL.Uniform1(_dstY1Uniform, (float)destination.Y2);
GL.DispatchCompute(dispatchX, dispatchY, 1);
GL.UseProgram(previousProgram);
GL.MemoryBarrier(MemoryBarrierFlags.ShaderImageAccessBarrierBit);
(_renderer.Pipeline as Pipeline).RestoreImages1And2();
GL.ActiveTexture(TextureUnit.Texture0);
GL.BindTexture(TextureTarget.Texture2D, previousTextureBinding);
GL.ActiveTexture((TextureUnit)previousUnit);
}
}
}

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@ -18,7 +18,7 @@ namespace Ryujinx.Graphics.OpenGL.Effects
private int _srcY0Uniform;
private int _scalingShaderProgram;
private int _sharpeningShaderProgram;
private float _scale = 1;
private float _sharpeningLevel = 1;
private int _srcY1Uniform;
private int _dstX0Uniform;
private int _dstX1Uniform;
@ -30,10 +30,10 @@ namespace Ryujinx.Graphics.OpenGL.Effects
public float Level
{
get => _scale;
get => _sharpeningLevel;
set
{
_scale = MathF.Max(0.01f, value);
_sharpeningLevel = MathF.Max(0.01f, value);
}
}

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@ -1,4 +1,5 @@
using OpenTK.Graphics.OpenGL;
using Ryujinx.Common.Logging;
namespace Ryujinx.Graphics.OpenGL.Effects
{
@ -6,18 +7,7 @@ namespace Ryujinx.Graphics.OpenGL.Effects
{
public static int CompileProgram(string shaderCode, ShaderType shaderType)
{
var shader = GL.CreateShader(shaderType);
GL.ShaderSource(shader, shaderCode);
GL.CompileShader(shader);
var program = GL.CreateProgram();
GL.AttachShader(program, shader);
GL.LinkProgram(program);
GL.DetachShader(program, shader);
GL.DeleteShader(shader);
return program;
return CompileProgram(new string[] { shaderCode }, shaderType);
}
public static int CompileProgram(string[] shaders, ShaderType shaderType)
@ -26,6 +16,15 @@ namespace Ryujinx.Graphics.OpenGL.Effects
GL.ShaderSource(shader, shaders.Length, shaders, (int[])null);
GL.CompileShader(shader);
GL.GetShader(shader, ShaderParameter.CompileStatus, out int isCompiled);
if (isCompiled == 0)
{
string log = GL.GetShaderInfoLog(shader);
Logger.Error?.Print(LogClass.Gpu, $"Failed to compile effect shader:\n\n{log}\n");
GL.DeleteShader(shader);
return 0;
}
var program = GL.CreateProgram();
GL.AttachShader(program, shader);
GL.LinkProgram(program);

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@ -0,0 +1,119 @@
#version 430 core
precision mediump float;
layout (local_size_x = 16, local_size_y = 16) in;
layout(rgba8, binding = 0, location=0) uniform image2D imgOutput;
layout( location=1 ) uniform sampler2D Source;
layout( location=2 ) uniform float srcX0;
layout( location=3 ) uniform float srcX1;
layout( location=4 ) uniform float srcY0;
layout( location=5 ) uniform float srcY1;
layout( location=6 ) uniform float dstX0;
layout( location=7 ) uniform float dstX1;
layout( location=8 ) uniform float dstY0;
layout( location=9 ) uniform float dstY1;
/***** Area Sampling *****/
// By Sam Belliveau and Filippo Tarpini. Public Domain license.
// Effectively a more accurate sharp bilinear filter when upscaling,
// that also works as a mathematically perfect downscale filter.
// https://entropymine.com/imageworsener/pixelmixing/
// https://github.com/obsproject/obs-studio/pull/1715
// https://legacy.imagemagick.org/Usage/filter/
vec4 AreaSampling(vec2 xy)
{
// Determine the sizes of the source and target images.
vec2 source_size = vec2(abs(srcX1 - srcX0), abs(srcY1 - srcY0));
vec2 target_size = vec2(abs(dstX1 - dstX0), abs(dstY1 - dstY0));
vec2 inverted_target_size = vec2(1.0) / target_size;
// Compute the top-left and bottom-right corners of the target pixel box.
vec2 t_beg = floor(xy - vec2(dstX0 < dstX1 ? dstX0 : dstX1, dstY0 < dstY1 ? dstY0 : dstY1));
vec2 t_end = t_beg + vec2(1.0, 1.0);
// Convert the target pixel box to source pixel box.
vec2 beg = t_beg * inverted_target_size * source_size;
vec2 end = t_end * inverted_target_size * source_size;
// Compute the top-left and bottom-right corners of the pixel box.
ivec2 f_beg = ivec2(beg);
ivec2 f_end = ivec2(end);
// Compute how much of the start and end pixels are covered horizontally & vertically.
float area_w = 1.0 - fract(beg.x);
float area_n = 1.0 - fract(beg.y);
float area_e = fract(end.x);
float area_s = fract(end.y);
// Compute the areas of the corner pixels in the pixel box.
float area_nw = area_n * area_w;
float area_ne = area_n * area_e;
float area_sw = area_s * area_w;
float area_se = area_s * area_e;
// Initialize the color accumulator.
vec4 avg_color = vec4(0.0, 0.0, 0.0, 0.0);
// Accumulate corner pixels.
avg_color += area_nw * texelFetch(Source, ivec2(f_beg.x, f_beg.y), 0);
avg_color += area_ne * texelFetch(Source, ivec2(f_end.x, f_beg.y), 0);
avg_color += area_sw * texelFetch(Source, ivec2(f_beg.x, f_end.y), 0);
avg_color += area_se * texelFetch(Source, ivec2(f_end.x, f_end.y), 0);
// Determine the size of the pixel box.
int x_range = int(f_end.x - f_beg.x - 0.5);
int y_range = int(f_end.y - f_beg.y - 0.5);
// Accumulate top and bottom edge pixels.
for (int x = f_beg.x + 1; x <= f_beg.x + x_range; ++x)
{
avg_color += area_n * texelFetch(Source, ivec2(x, f_beg.y), 0);
avg_color += area_s * texelFetch(Source, ivec2(x, f_end.y), 0);
}
// Accumulate left and right edge pixels and all the pixels in between.
for (int y = f_beg.y + 1; y <= f_beg.y + y_range; ++y)
{
avg_color += area_w * texelFetch(Source, ivec2(f_beg.x, y), 0);
avg_color += area_e * texelFetch(Source, ivec2(f_end.x, y), 0);
for (int x = f_beg.x + 1; x <= f_beg.x + x_range; ++x)
{
avg_color += texelFetch(Source, ivec2(x, y), 0);
}
}
// Compute the area of the pixel box that was sampled.
float area_corners = area_nw + area_ne + area_sw + area_se;
float area_edges = float(x_range) * (area_n + area_s) + float(y_range) * (area_w + area_e);
float area_center = float(x_range) * float(y_range);
// Return the normalized average color.
return avg_color / (area_corners + area_edges + area_center);
}
float insideBox(vec2 v, vec2 bLeft, vec2 tRight) {
vec2 s = step(bLeft, v) - step(tRight, v);
return s.x * s.y;
}
vec2 translateDest(vec2 pos) {
vec2 translatedPos = vec2(pos.x, pos.y);
translatedPos.x = dstX1 < dstX0 ? dstX1 - translatedPos.x : translatedPos.x;
translatedPos.y = dstY0 > dstY1 ? dstY0 + dstY1 - translatedPos.y - 1 : translatedPos.y;
return translatedPos;
}
void main()
{
vec2 bLeft = vec2(dstX0 < dstX1 ? dstX0 : dstX1, dstY0 < dstY1 ? dstY0 : dstY1);
vec2 tRight = vec2(dstX1 > dstX0 ? dstX1 : dstX0, dstY1 > dstY0 ? dstY1 : dstY0);
ivec2 loc = ivec2(gl_GlobalInvocationID.x, gl_GlobalInvocationID.y);
if (insideBox(loc, bLeft, tRight) == 0) {
imageStore(imgOutput, loc, vec4(0, 0, 0, 1));
return;
}
vec4 outColor = AreaSampling(loc);
imageStore(imgOutput, ivec2(translateDest(loc)), vec4(outColor.rgb, 1));
}

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@ -85,4 +85,4 @@ void main() {
CurrFilter(gxy);
gxy.x -= 8u;
CurrFilter(gxy);
}
}

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@ -21,6 +21,7 @@
<EmbeddedResource Include="Effects\Shaders\ffx_fsr1.h" />
<EmbeddedResource Include="Effects\Shaders\ffx_a.h" />
<EmbeddedResource Include="Effects\Shaders\fsr_scaling.glsl" />
<EmbeddedResource Include="Effects\Shaders\area_scaling.glsl" />
</ItemGroup>
<ItemGroup>

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@ -373,6 +373,16 @@ namespace Ryujinx.Graphics.OpenGL
_isLinear = false;
_scalingFilter.Level = _scalingFilterLevel;
RecreateUpscalingTexture();
break;
case ScalingFilter.Area:
if (_scalingFilter is not AreaScalingFilter)
{
_scalingFilter?.Dispose();
_scalingFilter = new AreaScalingFilter(_renderer);
}
_isLinear = false;
RecreateUpscalingTexture();
break;
}

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@ -0,0 +1,101 @@
using Ryujinx.Common;
using Ryujinx.Graphics.GAL;
using Ryujinx.Graphics.Shader;
using Ryujinx.Graphics.Shader.Translation;
using Silk.NET.Vulkan;
using System;
using Extent2D = Ryujinx.Graphics.GAL.Extents2D;
using Format = Silk.NET.Vulkan.Format;
using SamplerCreateInfo = Ryujinx.Graphics.GAL.SamplerCreateInfo;
namespace Ryujinx.Graphics.Vulkan.Effects
{
internal class AreaScalingFilter : IScalingFilter
{
private readonly VulkanRenderer _renderer;
private PipelineHelperShader _pipeline;
private ISampler _sampler;
private ShaderCollection _scalingProgram;
private Device _device;
public float Level { get; set; }
public AreaScalingFilter(VulkanRenderer renderer, Device device)
{
_device = device;
_renderer = renderer;
Initialize();
}
public void Dispose()
{
_pipeline.Dispose();
_scalingProgram.Dispose();
_sampler.Dispose();
}
public void Initialize()
{
_pipeline = new PipelineHelperShader(_renderer, _device);
_pipeline.Initialize();
var scalingShader = EmbeddedResources.Read("Ryujinx.Graphics.Vulkan/Effects/Shaders/AreaScaling.spv");
var scalingResourceLayout = new ResourceLayoutBuilder()
.Add(ResourceStages.Compute, ResourceType.UniformBuffer, 2)
.Add(ResourceStages.Compute, ResourceType.TextureAndSampler, 1)
.Add(ResourceStages.Compute, ResourceType.Image, 0, true).Build();
_sampler = _renderer.CreateSampler(SamplerCreateInfo.Create(MinFilter.Linear, MagFilter.Linear));
_scalingProgram = _renderer.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(scalingShader, ShaderStage.Compute, TargetLanguage.Spirv),
}, scalingResourceLayout);
}
public void Run(
TextureView view,
CommandBufferScoped cbs,
Auto<DisposableImageView> destinationTexture,
Format format,
int width,
int height,
Extent2D source,
Extent2D destination)
{
_pipeline.SetCommandBuffer(cbs);
_pipeline.SetProgram(_scalingProgram);
_pipeline.SetTextureAndSampler(ShaderStage.Compute, 1, view, _sampler);
ReadOnlySpan<float> dimensionsBuffer = stackalloc float[]
{
source.X1,
source.X2,
source.Y1,
source.Y2,
destination.X1,
destination.X2,
destination.Y1,
destination.Y2,
};
int rangeSize = dimensionsBuffer.Length * sizeof(float);
using var buffer = _renderer.BufferManager.ReserveOrCreate(_renderer, cbs, rangeSize);
buffer.Holder.SetDataUnchecked(buffer.Offset, dimensionsBuffer);
int threadGroupWorkRegionDim = 16;
int dispatchX = (width + (threadGroupWorkRegionDim - 1)) / threadGroupWorkRegionDim;
int dispatchY = (height + (threadGroupWorkRegionDim - 1)) / threadGroupWorkRegionDim;
_pipeline.SetUniformBuffers(stackalloc[] { new BufferAssignment(2, buffer.Range) });
_pipeline.SetImage(0, destinationTexture);
_pipeline.DispatchCompute(dispatchX, dispatchY, 1);
_pipeline.ComputeBarrier();
_pipeline.Finish();
}
}
}

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@ -0,0 +1,122 @@
// Scaling
#version 430 core
layout (local_size_x = 16, local_size_y = 16) in;
layout( rgba8, binding = 0, set = 3) uniform image2D imgOutput;
layout( binding = 1, set = 2) uniform sampler2D Source;
layout( binding = 2 ) uniform dimensions{
float srcX0;
float srcX1;
float srcY0;
float srcY1;
float dstX0;
float dstX1;
float dstY0;
float dstY1;
};
/***** Area Sampling *****/
// By Sam Belliveau and Filippo Tarpini. Public Domain license.
// Effectively a more accurate sharp bilinear filter when upscaling,
// that also works as a mathematically perfect downscale filter.
// https://entropymine.com/imageworsener/pixelmixing/
// https://github.com/obsproject/obs-studio/pull/1715
// https://legacy.imagemagick.org/Usage/filter/
vec4 AreaSampling(vec2 xy)
{
// Determine the sizes of the source and target images.
vec2 source_size = vec2(abs(srcX1 - srcX0), abs(srcY1 - srcY0));
vec2 target_size = vec2(abs(dstX1 - dstX0), abs(dstY1 - dstY0));
vec2 inverted_target_size = vec2(1.0) / target_size;
// Compute the top-left and bottom-right corners of the target pixel box.
vec2 t_beg = floor(xy - vec2(dstX0 < dstX1 ? dstX0 : dstX1, dstY0 < dstY1 ? dstY0 : dstY1));
vec2 t_end = t_beg + vec2(1.0, 1.0);
// Convert the target pixel box to source pixel box.
vec2 beg = t_beg * inverted_target_size * source_size;
vec2 end = t_end * inverted_target_size * source_size;
// Compute the top-left and bottom-right corners of the pixel box.
ivec2 f_beg = ivec2(beg);
ivec2 f_end = ivec2(end);
// Compute how much of the start and end pixels are covered horizontally & vertically.
float area_w = 1.0 - fract(beg.x);
float area_n = 1.0 - fract(beg.y);
float area_e = fract(end.x);
float area_s = fract(end.y);
// Compute the areas of the corner pixels in the pixel box.
float area_nw = area_n * area_w;
float area_ne = area_n * area_e;
float area_sw = area_s * area_w;
float area_se = area_s * area_e;
// Initialize the color accumulator.
vec4 avg_color = vec4(0.0, 0.0, 0.0, 0.0);
// Accumulate corner pixels.
avg_color += area_nw * texelFetch(Source, ivec2(f_beg.x, f_beg.y), 0);
avg_color += area_ne * texelFetch(Source, ivec2(f_end.x, f_beg.y), 0);
avg_color += area_sw * texelFetch(Source, ivec2(f_beg.x, f_end.y), 0);
avg_color += area_se * texelFetch(Source, ivec2(f_end.x, f_end.y), 0);
// Determine the size of the pixel box.
int x_range = int(f_end.x - f_beg.x - 0.5);
int y_range = int(f_end.y - f_beg.y - 0.5);
// Accumulate top and bottom edge pixels.
for (int x = f_beg.x + 1; x <= f_beg.x + x_range; ++x)
{
avg_color += area_n * texelFetch(Source, ivec2(x, f_beg.y), 0);
avg_color += area_s * texelFetch(Source, ivec2(x, f_end.y), 0);
}
// Accumulate left and right edge pixels and all the pixels in between.
for (int y = f_beg.y + 1; y <= f_beg.y + y_range; ++y)
{
avg_color += area_w * texelFetch(Source, ivec2(f_beg.x, y), 0);
avg_color += area_e * texelFetch(Source, ivec2(f_end.x, y), 0);
for (int x = f_beg.x + 1; x <= f_beg.x + x_range; ++x)
{
avg_color += texelFetch(Source, ivec2(x, y), 0);
}
}
// Compute the area of the pixel box that was sampled.
float area_corners = area_nw + area_ne + area_sw + area_se;
float area_edges = float(x_range) * (area_n + area_s) + float(y_range) * (area_w + area_e);
float area_center = float(x_range) * float(y_range);
// Return the normalized average color.
return avg_color / (area_corners + area_edges + area_center);
}
float insideBox(vec2 v, vec2 bLeft, vec2 tRight) {
vec2 s = step(bLeft, v) - step(tRight, v);
return s.x * s.y;
}
vec2 translateDest(vec2 pos) {
vec2 translatedPos = vec2(pos.x, pos.y);
translatedPos.x = dstX1 < dstX0 ? dstX1 - translatedPos.x : translatedPos.x;
translatedPos.y = dstY0 < dstY1 ? dstY1 + dstY0 - translatedPos.y - 1 : translatedPos.y;
return translatedPos;
}
void main()
{
vec2 bLeft = vec2(dstX0 < dstX1 ? dstX0 : dstX1, dstY0 < dstY1 ? dstY0 : dstY1);
vec2 tRight = vec2(dstX1 > dstX0 ? dstX1 : dstX0, dstY1 > dstY0 ? dstY1 : dstY0);
ivec2 loc = ivec2(gl_GlobalInvocationID.x, gl_GlobalInvocationID.y);
if (insideBox(loc, bLeft, tRight) == 0) {
imageStore(imgOutput, loc, vec4(0, 0, 0, 1));
return;
}
vec4 outColor = AreaSampling(loc);
imageStore(imgOutput, ivec2(translateDest(loc)), vec4(outColor.rgb, 1));
}

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@ -15,6 +15,7 @@
<ItemGroup>
<EmbeddedResource Include="Effects\Textures\SmaaAreaTexture.bin" />
<EmbeddedResource Include="Effects\Textures\SmaaSearchTexture.bin" />
<EmbeddedResource Include="Effects\Shaders\AreaScaling.spv" />
<EmbeddedResource Include="Effects\Shaders\FsrScaling.spv" />
<EmbeddedResource Include="Effects\Shaders\FsrSharpening.spv" />
<EmbeddedResource Include="Effects\Shaders\Fxaa.spv" />

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@ -568,6 +568,13 @@ namespace Ryujinx.Graphics.Vulkan
_scalingFilter.Level = _scalingFilterLevel;
break;
case ScalingFilter.Area:
if (_scalingFilter is not AreaScalingFilter)
{
_scalingFilter?.Dispose();
_scalingFilter = new AreaScalingFilter(_gd, _device);
}
break;
}
}
}

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@ -758,10 +758,11 @@
"GraphicsAATooltip": "Applies anti-aliasing to the game render.\n\nFXAA will blur most of the image, while SMAA will attempt to find jagged edges and smooth them out.\n\nNot recommended to use in conjunction with the FSR scaling filter.\n\nThis option can be changed while a game is running by clicking \"Apply\" below; you can simply move the settings window aside and experiment until you find your preferred look for a game.\n\nLeave on NONE if unsure.",
"GraphicsAALabel": "Anti-Aliasing:",
"GraphicsScalingFilterLabel": "Scaling Filter:",
"GraphicsScalingFilterTooltip": "Choose the scaling filter that will be applied when using resolution scale.\n\nBilinear works well for 3D games and is a safe default option.\n\nNearest is recommended for pixel art games.\n\nFSR 1.0 is merely a sharpening filter, not recommended for use with FXAA or SMAA.\n\nThis option can be changed while a game is running by clicking \"Apply\" below; you can simply move the settings window aside and experiment until you find your preferred look for a game.\n\nLeave on BILINEAR if unsure.",
"GraphicsScalingFilterTooltip": "Choose the scaling filter that will be applied when using resolution scale.\n\nBilinear works well for 3D games and is a safe default option.\n\nNearest is recommended for pixel art games.\n\nFSR 1.0 is merely a sharpening filter, not recommended for use with FXAA or SMAA.\n\nArea scaling is recommended when downscaling resolutions that are larger than the output window. It can be used to achieve a supersampled anti-aliasing effect when downscaling by more than 2x.\n\nThis option can be changed while a game is running by clicking \"Apply\" below; you can simply move the settings window aside and experiment until you find your preferred look for a game.\n\nLeave on BILINEAR if unsure.",
"GraphicsScalingFilterBilinear": "Bilinear",
"GraphicsScalingFilterNearest": "Nearest",
"GraphicsScalingFilterFsr": "FSR",
"GraphicsScalingFilterArea": "Area",
"GraphicsScalingFilterLevelLabel": "Level",
"GraphicsScalingFilterLevelTooltip": "Set FSR 1.0 sharpening level. Higher is sharper.",
"SmaaLow": "SMAA Low",

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@ -1,4 +1,4 @@
<UserControl
<UserControl
x:Class="Ryujinx.Ava.UI.Views.Settings.SettingsGraphicsView"
xmlns="https://github.com/avaloniaui"
xmlns:x="http://schemas.microsoft.com/winfx/2006/xaml"
@ -173,6 +173,9 @@
<ComboBoxItem>
<TextBlock Text="{locale:Locale GraphicsScalingFilterFsr}" />
</ComboBoxItem>
<ComboBoxItem>
<TextBlock Text="{locale:Locale GraphicsScalingFilterArea}" />
</ComboBoxItem>
</ComboBox>
<controls:SliderScroll Value="{Binding ScalingFilterLevel}"
ToolTip.Tip="{locale:Locale GraphicsScalingFilterLevelTooltip}"