385ee5c70b
This allows light sources to be specified in physical light units in addition to the regular energy multiplier. In order to avoid loss of precision at high values, brightness values are premultiplied by an exposure normalization value. In support of Physical Light Units this PR also renames CameraEffects to CameraAttributes.
503 lines
17 KiB
GLSL
503 lines
17 KiB
GLSL
#[vertex]
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#version 450
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#VERSION_DEFINES
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#ifdef MULTIVIEW
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#ifdef has_VK_KHR_multiview
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#extension GL_EXT_multiview : enable
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#endif
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#endif
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layout(location = 0) out vec2 uv_interp;
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void main() {
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vec2 base_arr[4] = vec2[](vec2(0.0, 0.0), vec2(0.0, 1.0), vec2(1.0, 1.0), vec2(1.0, 0.0));
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uv_interp = base_arr[gl_VertexIndex];
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gl_Position = vec4(uv_interp * 2.0 - 1.0, 0.0, 1.0);
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}
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#[fragment]
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#version 450
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#VERSION_DEFINES
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#ifdef MULTIVIEW
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#ifdef has_VK_KHR_multiview
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#extension GL_EXT_multiview : enable
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#define ViewIndex gl_ViewIndex
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#else // has_VK_KHR_multiview
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#define ViewIndex 0
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#endif // has_VK_KHR_multiview
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#endif //MULTIVIEW
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layout(location = 0) in vec2 uv_interp;
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#ifdef SUBPASS
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layout(input_attachment_index = 0, set = 0, binding = 0) uniform subpassInput input_color;
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#elif defined(MULTIVIEW)
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layout(set = 0, binding = 0) uniform sampler2DArray source_color;
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#else
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layout(set = 0, binding = 0) uniform sampler2D source_color;
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#endif
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layout(set = 1, binding = 0) uniform sampler2D source_auto_exposure;
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#ifdef MULTIVIEW
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layout(set = 2, binding = 0) uniform sampler2DArray source_glow;
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#else
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layout(set = 2, binding = 0) uniform sampler2D source_glow;
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#endif
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layout(set = 2, binding = 1) uniform sampler2D glow_map;
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#ifdef USE_1D_LUT
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layout(set = 3, binding = 0) uniform sampler2D source_color_correction;
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#else
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layout(set = 3, binding = 0) uniform sampler3D source_color_correction;
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#endif
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layout(push_constant, std430) uniform Params {
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vec3 bcs;
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bool use_bcs;
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bool use_glow;
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bool use_auto_exposure;
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bool use_color_correction;
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uint tonemapper;
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uvec2 glow_texture_size;
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float glow_intensity;
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float glow_map_strength;
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uint glow_mode;
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float glow_levels[7];
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float exposure;
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float white;
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float auto_exposure_scale;
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float luminance_multiplier;
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vec2 pixel_size;
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bool use_fxaa;
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bool use_debanding;
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}
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params;
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layout(location = 0) out vec4 frag_color;
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#ifdef USE_GLOW_FILTER_BICUBIC
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// w0, w1, w2, and w3 are the four cubic B-spline basis functions
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float w0(float a) {
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return (1.0f / 6.0f) * (a * (a * (-a + 3.0f) - 3.0f) + 1.0f);
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}
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float w1(float a) {
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return (1.0f / 6.0f) * (a * a * (3.0f * a - 6.0f) + 4.0f);
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}
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float w2(float a) {
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return (1.0f / 6.0f) * (a * (a * (-3.0f * a + 3.0f) + 3.0f) + 1.0f);
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}
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float w3(float a) {
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return (1.0f / 6.0f) * (a * a * a);
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}
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// g0 and g1 are the two amplitude functions
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float g0(float a) {
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return w0(a) + w1(a);
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}
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float g1(float a) {
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return w2(a) + w3(a);
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}
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// h0 and h1 are the two offset functions
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float h0(float a) {
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return -1.0f + w1(a) / (w0(a) + w1(a));
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}
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float h1(float a) {
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return 1.0f + w3(a) / (w2(a) + w3(a));
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}
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#ifdef MULTIVIEW
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vec4 texture2D_bicubic(sampler2DArray tex, vec2 uv, int p_lod) {
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float lod = float(p_lod);
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vec2 tex_size = vec2(params.glow_texture_size >> p_lod);
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vec2 pixel_size = vec2(1.0f) / tex_size;
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uv = uv * tex_size + vec2(0.5f);
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vec2 iuv = floor(uv);
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vec2 fuv = fract(uv);
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float g0x = g0(fuv.x);
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float g1x = g1(fuv.x);
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float h0x = h0(fuv.x);
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float h1x = h1(fuv.x);
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float h0y = h0(fuv.y);
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float h1y = h1(fuv.y);
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vec3 p0 = vec3((vec2(iuv.x + h0x, iuv.y + h0y) - vec2(0.5f)) * pixel_size, ViewIndex);
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vec3 p1 = vec3((vec2(iuv.x + h1x, iuv.y + h0y) - vec2(0.5f)) * pixel_size, ViewIndex);
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vec3 p2 = vec3((vec2(iuv.x + h0x, iuv.y + h1y) - vec2(0.5f)) * pixel_size, ViewIndex);
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vec3 p3 = vec3((vec2(iuv.x + h1x, iuv.y + h1y) - vec2(0.5f)) * pixel_size, ViewIndex);
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return (g0(fuv.y) * (g0x * textureLod(tex, p0, lod) + g1x * textureLod(tex, p1, lod))) +
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(g1(fuv.y) * (g0x * textureLod(tex, p2, lod) + g1x * textureLod(tex, p3, lod)));
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}
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#define GLOW_TEXTURE_SAMPLE(m_tex, m_uv, m_lod) texture2D_bicubic(m_tex, m_uv, m_lod)
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#else // MULTIVIEW
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vec4 texture2D_bicubic(sampler2D tex, vec2 uv, int p_lod) {
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float lod = float(p_lod);
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vec2 tex_size = vec2(params.glow_texture_size >> p_lod);
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vec2 pixel_size = vec2(1.0f) / tex_size;
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uv = uv * tex_size + vec2(0.5f);
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vec2 iuv = floor(uv);
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vec2 fuv = fract(uv);
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float g0x = g0(fuv.x);
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float g1x = g1(fuv.x);
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float h0x = h0(fuv.x);
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float h1x = h1(fuv.x);
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float h0y = h0(fuv.y);
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float h1y = h1(fuv.y);
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vec2 p0 = (vec2(iuv.x + h0x, iuv.y + h0y) - vec2(0.5f)) * pixel_size;
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vec2 p1 = (vec2(iuv.x + h1x, iuv.y + h0y) - vec2(0.5f)) * pixel_size;
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vec2 p2 = (vec2(iuv.x + h0x, iuv.y + h1y) - vec2(0.5f)) * pixel_size;
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vec2 p3 = (vec2(iuv.x + h1x, iuv.y + h1y) - vec2(0.5f)) * pixel_size;
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return (g0(fuv.y) * (g0x * textureLod(tex, p0, lod) + g1x * textureLod(tex, p1, lod))) +
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(g1(fuv.y) * (g0x * textureLod(tex, p2, lod) + g1x * textureLod(tex, p3, lod)));
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}
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#define GLOW_TEXTURE_SAMPLE(m_tex, m_uv, m_lod) texture2D_bicubic(m_tex, m_uv, m_lod)
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#endif // !MULTIVIEW
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#else // USE_GLOW_FILTER_BICUBIC
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#ifdef MULTIVIEW
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#define GLOW_TEXTURE_SAMPLE(m_tex, m_uv, m_lod) textureLod(m_tex, vec3(m_uv, ViewIndex), float(m_lod))
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#else // MULTIVIEW
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#define GLOW_TEXTURE_SAMPLE(m_tex, m_uv, m_lod) textureLod(m_tex, m_uv, float(m_lod))
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#endif // !MULTIVIEW
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#endif // !USE_GLOW_FILTER_BICUBIC
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vec3 tonemap_filmic(vec3 color, float white) {
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// exposure bias: input scale (color *= bias, white *= bias) to make the brightness consistent with other tonemappers
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// also useful to scale the input to the range that the tonemapper is designed for (some require very high input values)
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// has no effect on the curve's general shape or visual properties
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const float exposure_bias = 2.0f;
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const float A = 0.22f * exposure_bias * exposure_bias; // bias baked into constants for performance
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const float B = 0.30f * exposure_bias;
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const float C = 0.10f;
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const float D = 0.20f;
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const float E = 0.01f;
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const float F = 0.30f;
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vec3 color_tonemapped = ((color * (A * color + C * B) + D * E) / (color * (A * color + B) + D * F)) - E / F;
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float white_tonemapped = ((white * (A * white + C * B) + D * E) / (white * (A * white + B) + D * F)) - E / F;
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return color_tonemapped / white_tonemapped;
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}
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// Adapted from https://github.com/TheRealMJP/BakingLab/blob/master/BakingLab/ACES.hlsl
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// (MIT License).
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vec3 tonemap_aces(vec3 color, float white) {
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const float exposure_bias = 1.8f;
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const float A = 0.0245786f;
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const float B = 0.000090537f;
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const float C = 0.983729f;
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const float D = 0.432951f;
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const float E = 0.238081f;
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// Exposure bias baked into transform to save shader instructions. Equivalent to `color *= exposure_bias`
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const mat3 rgb_to_rrt = mat3(
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vec3(0.59719f * exposure_bias, 0.35458f * exposure_bias, 0.04823f * exposure_bias),
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vec3(0.07600f * exposure_bias, 0.90834f * exposure_bias, 0.01566f * exposure_bias),
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vec3(0.02840f * exposure_bias, 0.13383f * exposure_bias, 0.83777f * exposure_bias));
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const mat3 odt_to_rgb = mat3(
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vec3(1.60475f, -0.53108f, -0.07367f),
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vec3(-0.10208f, 1.10813f, -0.00605f),
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vec3(-0.00327f, -0.07276f, 1.07602f));
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color *= rgb_to_rrt;
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vec3 color_tonemapped = (color * (color + A) - B) / (color * (C * color + D) + E);
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color_tonemapped *= odt_to_rgb;
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white *= exposure_bias;
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float white_tonemapped = (white * (white + A) - B) / (white * (C * white + D) + E);
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return color_tonemapped / white_tonemapped;
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}
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vec3 tonemap_reinhard(vec3 color, float white) {
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return (white * color + color) / (color * white + white);
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}
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vec3 linear_to_srgb(vec3 color) {
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//if going to srgb, clamp from 0 to 1.
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color = clamp(color, vec3(0.0), vec3(1.0));
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const vec3 a = vec3(0.055f);
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return mix((vec3(1.0f) + a) * pow(color.rgb, vec3(1.0f / 2.4f)) - a, 12.92f * color.rgb, lessThan(color.rgb, vec3(0.0031308f)));
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}
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#define TONEMAPPER_LINEAR 0
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#define TONEMAPPER_REINHARD 1
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#define TONEMAPPER_FILMIC 2
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#define TONEMAPPER_ACES 3
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vec3 apply_tonemapping(vec3 color, float white) { // inputs are LINEAR, always outputs clamped [0;1] color
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// Ensure color values passed to tonemappers are positive.
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// They can be negative in the case of negative lights, which leads to undesired behavior.
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if (params.tonemapper == TONEMAPPER_LINEAR) {
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return color;
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} else if (params.tonemapper == TONEMAPPER_REINHARD) {
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return tonemap_reinhard(max(vec3(0.0f), color), white);
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} else if (params.tonemapper == TONEMAPPER_FILMIC) {
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return tonemap_filmic(max(vec3(0.0f), color), white);
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} else { // TONEMAPPER_ACES
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return tonemap_aces(max(vec3(0.0f), color), white);
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}
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}
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#ifdef MULTIVIEW
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vec3 gather_glow(sampler2DArray tex, vec2 uv) { // sample all selected glow levels, view is added to uv later
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#else
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vec3 gather_glow(sampler2D tex, vec2 uv) { // sample all selected glow levels
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#endif // defined(MULTIVIEW)
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vec3 glow = vec3(0.0f);
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if (params.glow_levels[0] > 0.0001) {
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glow += GLOW_TEXTURE_SAMPLE(tex, uv, 0).rgb * params.glow_levels[0];
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}
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if (params.glow_levels[1] > 0.0001) {
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glow += GLOW_TEXTURE_SAMPLE(tex, uv, 1).rgb * params.glow_levels[1];
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}
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if (params.glow_levels[2] > 0.0001) {
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glow += GLOW_TEXTURE_SAMPLE(tex, uv, 2).rgb * params.glow_levels[2];
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}
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if (params.glow_levels[3] > 0.0001) {
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glow += GLOW_TEXTURE_SAMPLE(tex, uv, 3).rgb * params.glow_levels[3];
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}
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if (params.glow_levels[4] > 0.0001) {
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glow += GLOW_TEXTURE_SAMPLE(tex, uv, 4).rgb * params.glow_levels[4];
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}
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if (params.glow_levels[5] > 0.0001) {
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glow += GLOW_TEXTURE_SAMPLE(tex, uv, 5).rgb * params.glow_levels[5];
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}
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if (params.glow_levels[6] > 0.0001) {
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glow += GLOW_TEXTURE_SAMPLE(tex, uv, 6).rgb * params.glow_levels[6];
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}
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return glow;
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}
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#define GLOW_MODE_ADD 0
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#define GLOW_MODE_SCREEN 1
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#define GLOW_MODE_SOFTLIGHT 2
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#define GLOW_MODE_REPLACE 3
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#define GLOW_MODE_MIX 4
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vec3 apply_glow(vec3 color, vec3 glow) { // apply glow using the selected blending mode
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if (params.glow_mode == GLOW_MODE_ADD) {
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return color + glow;
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} else if (params.glow_mode == GLOW_MODE_SCREEN) {
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//need color clamping
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return max((color + glow) - (color * glow), vec3(0.0));
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} else if (params.glow_mode == GLOW_MODE_SOFTLIGHT) {
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//need color clamping
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glow = glow * vec3(0.5f) + vec3(0.5f);
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color.r = (glow.r <= 0.5f) ? (color.r - (1.0f - 2.0f * glow.r) * color.r * (1.0f - color.r)) : (((glow.r > 0.5f) && (color.r <= 0.25f)) ? (color.r + (2.0f * glow.r - 1.0f) * (4.0f * color.r * (4.0f * color.r + 1.0f) * (color.r - 1.0f) + 7.0f * color.r)) : (color.r + (2.0f * glow.r - 1.0f) * (sqrt(color.r) - color.r)));
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color.g = (glow.g <= 0.5f) ? (color.g - (1.0f - 2.0f * glow.g) * color.g * (1.0f - color.g)) : (((glow.g > 0.5f) && (color.g <= 0.25f)) ? (color.g + (2.0f * glow.g - 1.0f) * (4.0f * color.g * (4.0f * color.g + 1.0f) * (color.g - 1.0f) + 7.0f * color.g)) : (color.g + (2.0f * glow.g - 1.0f) * (sqrt(color.g) - color.g)));
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color.b = (glow.b <= 0.5f) ? (color.b - (1.0f - 2.0f * glow.b) * color.b * (1.0f - color.b)) : (((glow.b > 0.5f) && (color.b <= 0.25f)) ? (color.b + (2.0f * glow.b - 1.0f) * (4.0f * color.b * (4.0f * color.b + 1.0f) * (color.b - 1.0f) + 7.0f * color.b)) : (color.b + (2.0f * glow.b - 1.0f) * (sqrt(color.b) - color.b)));
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return color;
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} else { //replace
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return glow;
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}
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}
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vec3 apply_bcs(vec3 color, vec3 bcs) {
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color = mix(vec3(0.0f), color, bcs.x);
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color = mix(vec3(0.5f), color, bcs.y);
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color = mix(vec3(dot(vec3(1.0f), color) * 0.33333f), color, bcs.z);
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return color;
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}
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#ifdef USE_1D_LUT
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vec3 apply_color_correction(vec3 color) {
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color.r = texture(source_color_correction, vec2(color.r, 0.0f)).r;
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color.g = texture(source_color_correction, vec2(color.g, 0.0f)).g;
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color.b = texture(source_color_correction, vec2(color.b, 0.0f)).b;
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return color;
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}
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#else
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vec3 apply_color_correction(vec3 color) {
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return textureLod(source_color_correction, color, 0.0).rgb;
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}
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#endif
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#ifndef SUBPASS
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vec3 do_fxaa(vec3 color, float exposure, vec2 uv_interp) {
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const float FXAA_REDUCE_MIN = (1.0 / 128.0);
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const float FXAA_REDUCE_MUL = (1.0 / 8.0);
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const float FXAA_SPAN_MAX = 8.0;
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#ifdef MULTIVIEW
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vec3 rgbNW = textureLod(source_color, vec3(uv_interp + vec2(-1.0, -1.0) * params.pixel_size, ViewIndex), 0.0).xyz * exposure * params.luminance_multiplier;
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vec3 rgbNE = textureLod(source_color, vec3(uv_interp + vec2(1.0, -1.0) * params.pixel_size, ViewIndex), 0.0).xyz * exposure * params.luminance_multiplier;
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vec3 rgbSW = textureLod(source_color, vec3(uv_interp + vec2(-1.0, 1.0) * params.pixel_size, ViewIndex), 0.0).xyz * exposure * params.luminance_multiplier;
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vec3 rgbSE = textureLod(source_color, vec3(uv_interp + vec2(1.0, 1.0) * params.pixel_size, ViewIndex), 0.0).xyz * exposure * params.luminance_multiplier;
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#else
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vec3 rgbNW = textureLod(source_color, uv_interp + vec2(-1.0, -1.0) * params.pixel_size, 0.0).xyz * exposure * params.luminance_multiplier;
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vec3 rgbNE = textureLod(source_color, uv_interp + vec2(1.0, -1.0) * params.pixel_size, 0.0).xyz * exposure * params.luminance_multiplier;
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vec3 rgbSW = textureLod(source_color, uv_interp + vec2(-1.0, 1.0) * params.pixel_size, 0.0).xyz * exposure * params.luminance_multiplier;
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vec3 rgbSE = textureLod(source_color, uv_interp + vec2(1.0, 1.0) * params.pixel_size, 0.0).xyz * exposure * params.luminance_multiplier;
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#endif
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vec3 rgbM = color;
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vec3 luma = vec3(0.299, 0.587, 0.114);
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float lumaNW = dot(rgbNW, luma);
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float lumaNE = dot(rgbNE, luma);
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float lumaSW = dot(rgbSW, luma);
|
|
float lumaSE = dot(rgbSE, luma);
|
|
float lumaM = dot(rgbM, luma);
|
|
float lumaMin = min(lumaM, min(min(lumaNW, lumaNE), min(lumaSW, lumaSE)));
|
|
float lumaMax = max(lumaM, max(max(lumaNW, lumaNE), max(lumaSW, lumaSE)));
|
|
|
|
vec2 dir;
|
|
dir.x = -((lumaNW + lumaNE) - (lumaSW + lumaSE));
|
|
dir.y = ((lumaNW + lumaSW) - (lumaNE + lumaSE));
|
|
|
|
float dirReduce = max((lumaNW + lumaNE + lumaSW + lumaSE) *
|
|
(0.25 * FXAA_REDUCE_MUL),
|
|
FXAA_REDUCE_MIN);
|
|
|
|
float rcpDirMin = 1.0 / (min(abs(dir.x), abs(dir.y)) + dirReduce);
|
|
dir = min(vec2(FXAA_SPAN_MAX, FXAA_SPAN_MAX),
|
|
max(vec2(-FXAA_SPAN_MAX, -FXAA_SPAN_MAX),
|
|
dir * rcpDirMin)) *
|
|
params.pixel_size;
|
|
|
|
#ifdef MULTIVIEW
|
|
vec3 rgbA = 0.5 * exposure * (textureLod(source_color, vec3(uv_interp + dir * (1.0 / 3.0 - 0.5), ViewIndex), 0.0).xyz + textureLod(source_color, vec3(uv_interp + dir * (2.0 / 3.0 - 0.5), ViewIndex), 0.0).xyz) * params.luminance_multiplier;
|
|
vec3 rgbB = rgbA * 0.5 + 0.25 * exposure * (textureLod(source_color, vec3(uv_interp + dir * -0.5, ViewIndex), 0.0).xyz + textureLod(source_color, vec3(uv_interp + dir * 0.5, ViewIndex), 0.0).xyz) * params.luminance_multiplier;
|
|
#else
|
|
vec3 rgbA = 0.5 * exposure * (textureLod(source_color, uv_interp + dir * (1.0 / 3.0 - 0.5), 0.0).xyz + textureLod(source_color, uv_interp + dir * (2.0 / 3.0 - 0.5), 0.0).xyz) * params.luminance_multiplier;
|
|
vec3 rgbB = rgbA * 0.5 + 0.25 * exposure * (textureLod(source_color, uv_interp + dir * -0.5, 0.0).xyz + textureLod(source_color, uv_interp + dir * 0.5, 0.0).xyz) * params.luminance_multiplier;
|
|
#endif
|
|
|
|
float lumaB = dot(rgbB, luma);
|
|
if ((lumaB < lumaMin) || (lumaB > lumaMax)) {
|
|
return rgbA;
|
|
} else {
|
|
return rgbB;
|
|
}
|
|
}
|
|
#endif // !SUBPASS
|
|
|
|
// From https://alex.vlachos.com/graphics/Alex_Vlachos_Advanced_VR_Rendering_GDC2015.pdf
|
|
// and https://www.shadertoy.com/view/MslGR8 (5th one starting from the bottom)
|
|
// NOTE: `frag_coord` is in pixels (i.e. not normalized UV).
|
|
vec3 screen_space_dither(vec2 frag_coord) {
|
|
// Iestyn's RGB dither (7 asm instructions) from Portal 2 X360, slightly modified for VR.
|
|
vec3 dither = vec3(dot(vec2(171.0, 231.0), frag_coord));
|
|
dither.rgb = fract(dither.rgb / vec3(103.0, 71.0, 97.0));
|
|
|
|
// Subtract 0.5 to avoid slightly brightening the whole viewport.
|
|
return (dither.rgb - 0.5) / 255.0;
|
|
}
|
|
|
|
void main() {
|
|
#ifdef SUBPASS
|
|
// SUBPASS and MULTIVIEW can be combined but in that case we're already reading from the correct layer
|
|
vec4 color = subpassLoad(input_color);
|
|
#elif defined(MULTIVIEW)
|
|
vec4 color = textureLod(source_color, vec3(uv_interp, ViewIndex), 0.0f);
|
|
#else
|
|
vec4 color = textureLod(source_color, uv_interp, 0.0f);
|
|
#endif
|
|
color.rgb *= params.luminance_multiplier;
|
|
|
|
// Exposure
|
|
|
|
float exposure = params.exposure;
|
|
|
|
#ifndef SUBPASS
|
|
if (params.use_auto_exposure) {
|
|
exposure *= 1.0 / (texelFetch(source_auto_exposure, ivec2(0, 0), 0).r * params.luminance_multiplier / params.auto_exposure_scale);
|
|
}
|
|
#endif
|
|
|
|
color.rgb *= exposure;
|
|
|
|
// Early Tonemap & SRGB Conversion
|
|
#ifndef SUBPASS
|
|
if (params.use_fxaa) {
|
|
// FXAA must be performed before glow to preserve the "bleed" effect of glow.
|
|
color.rgb = do_fxaa(color.rgb, exposure, uv_interp);
|
|
}
|
|
|
|
if (params.use_glow && params.glow_mode == GLOW_MODE_MIX) {
|
|
vec3 glow = gather_glow(source_glow, uv_interp) * params.luminance_multiplier;
|
|
if (params.glow_map_strength > 0.001) {
|
|
glow = mix(glow, texture(glow_map, uv_interp).rgb * glow, params.glow_map_strength);
|
|
}
|
|
color.rgb = mix(color.rgb, glow, params.glow_intensity);
|
|
}
|
|
#endif
|
|
|
|
if (params.use_debanding) {
|
|
// For best results, debanding should be done before tonemapping.
|
|
// Otherwise, we're adding noise to an already-quantized image.
|
|
color.rgb += screen_space_dither(gl_FragCoord.xy);
|
|
}
|
|
|
|
color.rgb = apply_tonemapping(color.rgb, params.white);
|
|
|
|
color.rgb = linear_to_srgb(color.rgb); // regular linear -> SRGB conversion
|
|
|
|
#ifndef SUBPASS
|
|
// Glow
|
|
if (params.use_glow && params.glow_mode != GLOW_MODE_MIX) {
|
|
vec3 glow = gather_glow(source_glow, uv_interp) * params.glow_intensity * params.luminance_multiplier;
|
|
if (params.glow_map_strength > 0.001) {
|
|
glow = mix(glow, texture(glow_map, uv_interp).rgb * glow, params.glow_map_strength);
|
|
}
|
|
|
|
// high dynamic range -> SRGB
|
|
glow = apply_tonemapping(glow, params.white);
|
|
glow = linear_to_srgb(glow);
|
|
|
|
color.rgb = apply_glow(color.rgb, glow);
|
|
}
|
|
#endif
|
|
|
|
// Additional effects
|
|
|
|
if (params.use_bcs) {
|
|
color.rgb = apply_bcs(color.rgb, params.bcs);
|
|
}
|
|
|
|
if (params.use_color_correction) {
|
|
color.rgb = apply_color_correction(color.rgb);
|
|
}
|
|
|
|
frag_color = color;
|
|
}
|