Added slang shaders for hdr and graphics pipeline library samples

shaders/slang/_rename.py

@@ -16,7 +16,11 @@ def checkRenameFiles(samplename):
             mappings = {
                 "normaldebug.vert.spv": "base.vert.spv",
                 "normaldebug.frag.spv": "base.frag.spv",
-            }        
+            }
+        case "graphicspipelinelibrary":
+            mappings = {
+                "uber.vert.spv": "shared.vert.spv",
+            }             
         case "raytracingbasic":
             mappings = {
                 "raytracingbasic.rchit.spv": "closesthit.rchit.spv",

shaders/slang/graphicspipelinelibrary/uber.slang

@@ -0,0 +1,99 @@
+/* Copyright (c) 2025, Sascha Willems
+ *
+ * SPDX-License-Identifier: MIT
+ *
+ */
+
+struct VSInput
+{
+    float3 Pos;
+    float3 Normal;
+    float3 Color;
+};
+
+struct VSOutput
+{
+    float4 Pos : SV_POSITION;
+    float3 Normal;
+    float3 Color;
+    float3 ViewVec;
+    float3 LightVec;
+};
+
+struct UBO
+{
+    float4x4 projection;
+    float4x4 model;
+    float4 lightPos;
+};
+ConstantBuffer<UBO> ubo;
+
+// We use this constant to control the flow of the shader depending on the
+// lighting model selected at pipeline creation time
+[[SpecializationConstant]] const int LIGHTING_MODEL = 0;
+
+[shader("vertex")]
+VSOutput vertexMain(VSInput input)
+{
+    VSOutput output;
+    output.Color = input.Color;
+    output.Pos = mul(ubo.projection, mul(ubo.model, float4(input.Pos.xyz, 1.0)));
+    float4 pos = mul(ubo.model, float4(input.Pos, 1.0));
+    output.Normal = mul((float3x3)ubo.model, input.Normal);
+    float3 lPos = mul((float3x3)ubo.model, ubo.lightPos.xyz);
+    output.LightVec = lPos - pos.xyz;
+    output.ViewVec = -pos.xyz;
+    return output;
+}
+
+[shader("fragment")]
+float4 fragmentMain(VSOutput input)
+{
+    float3 outColor = float3(0.0);
+
+    switch (LIGHTING_MODEL) {
+    case 0: // Phong
+    {
+        float3 ambient = input.Color * float3(0.25, 0.25, 0.25);
+        float3 N = normalize(input.Normal);
+        float3 L = normalize(input.LightVec);
+        float3 V = normalize(input.ViewVec);
+        float3 R = reflect(-L, N);
+        float3 diffuse = max(dot(N, L), 0.0) * input.Color;
+        float3 specular = pow(max(dot(R, V), 0.0), 32.0) * float3(0.75);
+        outColor = ambient + diffuse * 1.75 + specular;
+		break;
+    }
+    case 1: // Toon
+    {
+
+        float3 N = normalize(input.Normal);
+        float3 L = normalize(input.LightVec);
+        float intensity = dot(N, L);
+        float3 color;
+        if (intensity > 0.98)
+            color = input.Color * 1.5;
+        else if (intensity > 0.9)
+            color = input.Color * 1.0;
+        else if (intensity > 0.5)
+            color = input.Color * 0.6;
+        else if (intensity > 0.25)
+            color = input.Color * 0.4;
+        else
+            color = input.Color * 0.2;
+        outColor = color;
+        break;
+    }
+    case 2: // No shading
+    {
+        outColor = input.Color;
+        break;
+    }
+    case 3: // Greyscale
+        outColor = dot(input.Color, float3(0.299, 0.587, 0.114));
+        break;
+    }
+
+    // The scene itself is a bit dark, so brigthen it up a bit
+    return float4(outColor * 1.25, 1.0);
+}

shaders/slang/hdr/bloom.slang

@@ -0,0 +1,80 @@
+/* Copyright (c) 2025, Sascha Willems
+ *
+ * SPDX-License-Identifier: MIT
+ *
+ */
+
+struct VSOutput
+{
+    float4 Pos : SV_POSITION;
+    float2 UV;
+};
+
+Sampler2D samplerColor0;
+Sampler2D samplerColor1;
+
+[[SpecializationConstant]] const int dir = 0;
+
+[shader("vertex")]
+VSOutput vertexMain(uint VertexIndex: SV_VertexID)
+{
+    VSOutput output;
+    output.UV = float2((VertexIndex << 1) & 2, VertexIndex & 2);
+    output.Pos = float4(output.UV * 2.0f - 1.0f, 0.0f, 1.0f);
+    return output;
+}
+
+[shader("fragment")]
+float4 fragmentMain(VSOutput input)
+{
+	// From the OpenGL Super bible
+	const float weights[] = {	0.0024499299678342,
+								0.0043538453346397,
+								0.0073599963704157,
+								0.0118349786570722,
+								0.0181026699707781,
+								0.0263392293891488,
+								0.0364543006660986,
+								0.0479932050577658,
+								0.0601029809166942,
+								0.0715974486241365,
+								0.0811305381519717,
+								0.0874493212267511,
+								0.0896631113333857,
+								0.0874493212267511,
+								0.0811305381519717,
+								0.0715974486241365,
+								0.0601029809166942,
+								0.0479932050577658,
+								0.0364543006660986,
+								0.0263392293891488,
+								0.0181026699707781,
+								0.0118349786570722,
+								0.0073599963704157,
+								0.0043538453346397,
+								0.0024499299678342};
+
+
+	const float blurScale = 0.003;
+	const float blurStrength = 1.0;
+
+	float ar = 1.0;
+	// Aspect ratio for vertical blur pass
+	if (dir == 1)
+	{
+        float2 ts;
+        samplerColor1.GetDimensions(ts.x, ts.y);
+		ar = ts.y / ts.x;
+	}
+
+	float2 P = input.UV.yx - float2(0, (25 >> 1) * ar * blurScale);
+
+	float4 color = float4(0.0, 0.0, 0.0, 0.0);
+	for (int i = 0; i < 25; i++)
+	{
+        float2 dv = float2(0.0, i * blurScale) * ar;
+        color += samplerColor1.Sample(P + dv) * weights[i] * blurStrength;
+	}
+
+	return color;
+}

shaders/slang/hdr/composition.slang

@@ -0,0 +1,28 @@
+/* Copyright (c) 2025, Sascha Willems
+ *
+ * SPDX-License-Identifier: MIT
+ *
+ */
+
+struct VSOutput
+{
+    float4 Pos : SV_POSITION;
+    float2 UV;
+};
+
+Sampler2D samplerColor;
+
+[shader("vertex")]
+VSOutput vertexMain(uint VertexIndex: SV_VertexID)
+{
+    VSOutput output;
+    output.UV = float2((VertexIndex << 1) & 2, VertexIndex & 2);
+    output.Pos = float4(output.UV * 2.0f - 1.0f, 0.0f, 1.0f);
+    return output;
+}
+
+[shader("fragment")]
+float4 fragmentMain(VSOutput input)
+{
+    return samplerColor.Sample(input.UV);
+}

shaders/slang/hdr/gbuffer.slang

@@ -0,0 +1,135 @@
+/* Copyright (c) 2025, Sascha Willems
+ *
+ * SPDX-License-Identifier: MIT
+ *
+ */
+
+struct VSInput
+{
+    float3 Pos;
+    float3 Normal;
+};
+
+struct VSOutput
+{
+    float4 Pos : SV_POSITION;
+    float3 UVW;
+    float3 WorldPos;
+    float3 Normal;
+    float3 ViewVec;
+    float3 LightVec;
+};
+
+struct FSOutput
+{
+	float4 Color0 : SV_TARGET0;
+	float4 Color1 : SV_TARGET1;
+};
+
+struct UBO  {
+	float4x4 projection;
+	float4x4 modelview;
+	float4x4 inverseModelview;
+	float exposure;
+};
+ConstantBuffer<UBO> ubo;
+
+SamplerCube samplerEnvMap;
+
+[[SpecializationConstant]] const int objectType = 0;
+
+[shader("vertex")]
+VSOutput vertexMain(VSInput input)
+{
+    VSOutput output;
+    output.UVW = input.Pos;
+
+    switch (objectType) {
+		case 0: // Skybox
+			output.WorldPos = mul((float4x3)ubo.modelview, input.Pos).xyz;
+			output.Pos = mul(ubo.projection, float4(output.WorldPos, 1.0));
+			break;
+		case 1: // Object
+			output.WorldPos = mul(ubo.modelview, float4(input.Pos, 1.0)).xyz;
+			output.Pos = mul(ubo.projection, mul(ubo.modelview, float4(input.Pos.xyz, 1.0)));
+            break;
+	}
+    output.WorldPos = mul(ubo.modelview, float4(input.Pos, 1.0)).xyz;
+    output.Normal = mul((float4x3)ubo.modelview, input.Normal).xyz;
+    float3 lightPos = float3(0.0f, -5.0f, 5.0f);
+    output.LightVec = lightPos.xyz - output.WorldPos.xyz;
+    output.ViewVec = -output.WorldPos.xyz;
+    return output;
+}
+
+[shader("fragment")]
+FSOutput fragmentMain(VSOutput input)
+{
+	FSOutput output;
+	float4 color;
+	float3 wcNormal;
+
+    switch (objectType) {
+		case 0: // Skybox
+			{
+                float3 normal = normalize(input.UVW);
+                color = samplerEnvMap.Sample(normal);
+			}
+			break;
+
+		case 1: // Reflect
+			{
+				float3 wViewVec = mul((float4x3)ubo.inverseModelview, normalize(input.ViewVec)).xyz;
+				float3 normal = normalize(input.Normal);
+				float3 wNormal = mul((float4x3)ubo.inverseModelview, normal).xyz;
+
+				float NdotL = max(dot(normal, input.LightVec), 0.0);
+
+				float3 eyeDir = normalize(input.ViewVec);
+				float3 halfVec = normalize(input.LightVec + eyeDir);
+				float NdotH = max(dot(normal, halfVec), 0.0);
+				float NdotV = max(dot(normal, eyeDir), 0.0);
+				float VdotH = max(dot(eyeDir, halfVec), 0.0);
+
+				// Geometric attenuation
+				float NH2 = 2.0 * NdotH;
+				float g1 = (NH2 * NdotV) / VdotH;
+				float g2 = (NH2 * NdotL) / VdotH;
+				float geoAtt = min(1.0, min(g1, g2));
+
+				const float F0 = 0.6;
+				const float k = 0.2;
+
+				// Fresnel (schlick approximation)
+				float fresnel = pow(1.0 - VdotH, 5.0);
+				fresnel *= (1.0 - F0);
+				fresnel += F0;
+
+				float spec = (fresnel * geoAtt) / (NdotV * NdotL * 3.14);
+
+                color = samplerEnvMap.Sample(reflect(-wViewVec, wNormal));
+
+				color = float4(color.rgb * NdotL * (k + spec * (1.0 - k)), 1.0);
+			}
+			break;
+
+		case 2: // Refract
+			{
+				float3 wViewVec = mul((float4x3)ubo.inverseModelview, normalize(input.ViewVec)).xyz;
+                float3 wNormal = mul((float4x3)ubo.inverseModelview, input.Normal).xyz;
+                color = samplerEnvMap.Sample(refract(-wViewVec, wNormal, 1.0/1.6));
+			}
+			break;
+	}
+
+
+	// Color with manual exposure into attachment 0
+	output.Color0.rgb = float3(1.0, 1.0, 1.0) - exp(-color.rgb * ubo.exposure);
+
+	// Bright parts for bloom into attachment 1
+	float l = dot(output.Color0.rgb, float3(0.2126, 0.7152, 0.0722));
+	float threshold = 0.75;
+	output.Color1.rgb = (l > threshold) ? output.Color0.rgb : float3(0.0, 0.0, 0.0);
+	output.Color1.a = 1.0;
+	return output;
+}