Merge pull request #12603 from Sam-Belliveau/oklab_resampling

Add HDR to Metal + Perceptual HDR
2024-03-20 22:45:10 -04:00 · 2024-03-20 22:45:10 -04:00 · 03f2b99ffe
parent b19cf1f962 fba333dde5
commit 03f2b99ffe
4 changed files with 128 additions and 0 deletions
--- a/Data/Sys/Shaders/PerceptualHDR.glsl
+++ b/Data/Sys/Shaders/PerceptualHDR.glsl
@ -0,0 +1,109 @@
+/*
+[configuration]
+
+[OptionRangeFloat]
+GUIName = Amplificiation
+OptionName = AMPLIFICATION
+MinValue = 1.0
+MaxValue = 6.0
+StepAmount = 0.25
+DefaultValue = 2.5
+
+[/configuration]
+*/
+
+// ICtCP Colorspace as defined by Dolby here:
+// https://professional.dolby.com/siteassets/pdfs/ictcp_dolbywhitepaper_v071.pdf
+
+/***** Transfer Function *****/
+
+const float4 m_1 = float4(2610.0 / 16384.0);
+const float4 m_2 = float4(128.0 * 2523.0 / 4096.0);
+const float4 m_1_inv = float4(16384.0 / 2610.0);
+const float4 m_2_inv = float4(4096.0 / (128.0 * 2523.0));
+
+const float4 c_1 = float4(3424.0 / 4096.0);
+const float4 c_2 = float4(2413.0 / 4096.0 * 32.0);
+const float4 c_3 = float4(2392.0 / 4096.0 * 32.0);
+
+float4 EOTF_inv(float4 lms) {
+    float4 y = pow(lms, m_1);
+    return pow((c_1 + c_2 * y) / (1.0 + c_3 * y), m_2);
+}
+
+float4 EOTF(float4 lms) {
+    float4 x = pow(lms, m_2_inv);
+    return pow(-(x - c_1) / (c_3 * x - c_2), m_1_inv);
+}
+
+// This is required as scaling in EOTF space is not linear.
+float EOTF_AMPLIFICATION = EOTF_inv(float4(AMPLIFICATION)).x;
+
+/***** Linear <--> ICtCp *****/
+
+const mat4 RGBtoLMS = mat4(
+    1688.0, 683.0,  99.0,   0.0,
+    2146.0, 2951.0, 309.0,  0.0,
+    262.0,  462.0,  3688.0, 0.0,
+    0.0,    0.0,    0.0,    4096.0) / 4096.0;
+
+const mat4 LMStoICtCp = mat4(
+    +2048.0, +6610.0,  +17933.0, 0.0,
+    +2048.0, -13613.0, -17390.0, 0.0,
+    +0.0,    +7003.0,  -543.0,   0.0,
+    +0.0,    +0.0,     +0.0,     4096.0) / 4096.0;
+
+float4 LinearRGBToICtCP(float4 c)
+{
+    return LMStoICtCp * EOTF_inv(RGBtoLMS * c);
+}
+
+/***** ICtCp <--> Linear *****/
+
+mat4 ICtCptoLMS = inverse(LMStoICtCp);
+mat4 LMStoRGB = inverse(RGBtoLMS);
+
+float4 ICtCpToLinearRGB(float4 c)
+{
+    return LMStoRGB * EOTF(ICtCptoLMS * c);
+}
+
+void main()
+{
+    float4 color = Sample();
+
+    // Nothing to do here, we are in SDR
+    if (!OptionEnabled(hdr_output) || !OptionEnabled(linear_space_output)) {
+        SetOutput(color);
+        return;
+    }
+
+    // Renormalize Color to be in [0.0 - 1.0] SDR Space. We will revert this later.
+    const float hdr_paper_white = hdr_paper_white_nits / hdr_sdr_white_nits;
+    color.rgb /= hdr_paper_white;
+
+    // Convert Color to Perceptual Color Space. This will allow us to do perceptual
+    // scaling while also being able to use the luminance channel.
+    float4 ictcp_color = LinearRGBToICtCP(color);
+
+    // Scale the color in perceptual space depending on the percieved luminance.
+    //
+    // At low luminances, ~0.0, pow(EOTF_AMPLIFICATION, ~0.0) ~= 1.0, so the
+    // color will appear to be unchanged. This is important as we don't want to
+    // over expose dark colors which would not have otherwise been seen.
+    //
+    // At high luminances, ~1.0, pow(EOTF_AMPLIFICATION, ~1.0) ~= EOTF_AMPLIFICATION,
+    // which is equivilant to scaling the color by EOTF_AMPLIFICATION. This is
+    // important as we want to get the most out of the display, and we want to
+    // get bright colors to hit their target brightness.
+    //
+    // For more information, see this desmos demonstrating this scaling process:
+    // https://www.desmos.com/calculator/syjyrjsj5c
+    const float luminance = ictcp_color.x;
+    ictcp_color *= pow(EOTF_AMPLIFICATION, luminance);
+
+    // Convert back to Linear RGB and output the color to the display.
+    // We use hdr_paper_white to renormalize the color to the comfortable
+    // SDR viewing range.
+    SetOutput(hdr_paper_white * ICtCpToLinearRGB(ictcp_color));
+}
--- a/Source/Core/VideoBackends/Metal/MTLMain.mm
+++ b/Source/Core/VideoBackends/Metal/MTLMain.mm
@ -164,8 +164,23 @@ void Metal::VideoBackend::PrepareWindow(WindowSystemInfo& wsi)
    return;
  NSView* view = static_cast<NSView*>(wsi.render_surface);
  CAMetalLayer* layer = [CAMetalLayer layer];
+
+  Util::PopulateBackendInfo(&g_Config);
+
+  if (g_Config.backend_info.bSupportsHDROutput && g_Config.bHDR)
+  {
+    [layer setWantsExtendedDynamicRangeContent:YES];
+    [layer setPixelFormat:MTLPixelFormatRGBA16Float];
+
+    const CFStringRef name = kCGColorSpaceExtendedLinearSRGB;
+    CGColorSpaceRef colorspace = CGColorSpaceCreateWithName(name);
+    [layer setColorspace:colorspace];
+    CGColorSpaceRelease(colorspace);
+  }
+
  [view setWantsLayer:YES];
  [view setLayer:layer];
+
  wsi.render_surface = layer;
 #endif
 }
--- a/Source/Core/VideoBackends/Metal/MTLUtil.h
+++ b/Source/Core/VideoBackends/Metal/MTLUtil.h
@ -3,7 +3,9 @@

 #pragma once

+#include <AppKit/NSScreen.h>
 #include <Metal/Metal.h>
+
 #include <vector>

 #include "VideoCommon/AbstractShader.h"
--- a/Source/Core/VideoBackends/Metal/MTLUtil.mm
+++ b/Source/Core/VideoBackends/Metal/MTLUtil.mm
@ -77,6 +77,8 @@ void Metal::Util::PopulateBackendInfo(VideoConfig* config)
  config->backend_info.bSupportsPartialMultisampleResolve = false;
  config->backend_info.bSupportsDynamicVertexLoader = true;
  config->backend_info.bSupportsVSLinePointExpand = true;
+  config->backend_info.bSupportsHDROutput =
+      1.0 < [[NSScreen deepestScreen] maximumPotentialExtendedDynamicRangeColorComponentValue];
 }

 void Metal::Util::PopulateBackendInfoAdapters(VideoConfig* config,