Added slang shaders for deferred shadows sample

2025-05-20 20:11:11 +02:00 · 2025-05-20 20:11:11 +02:00 · 6183ad5b89
commit 6183ad5b89
parent 9ff0f35f24
3 changed files with 327 additions and 0 deletions
--- a/shaders/slang/deferredshadows/deferred.slang
+++ b/shaders/slang/deferredshadows/deferred.slang
@ -0,0 +1,187 @@
 // Copyright 2020 Google LLC
 #define LIGHT_COUNT 3
 #define SHADOW_FACTOR 0.25
 #define AMBIENT_LIGHT 0.1
 #define USE_PCF
 struct VSOutput
 {
    float4 Pos : SV_POSITION;
    float2 UV;
 };
 [[vk::binding(1, 0)]] Sampler2D samplerPosition;
 [[vk::binding(2, 0)]] Sampler2D samplerNormal;
 [[vk::binding(3, 0)]] Sampler2D samplerAlbedo;
 struct Light
 {
    float4 position;
    float4 target;
    float4 color;
    float4x4 viewMatrix;
 };
 struct UBO
 {
 	float4 viewPos;
 	Light lights[LIGHT_COUNT];
 	int useShadows;
 	int displayDebugTarget;
 };
 [[vk::binding(4, 0)]] ConstantBuffer<UBO> ubo;
 // Depth from the light's point of view
 // layout (binding = 5) uniform sampler2DShadow samplerShadowMap;
 [[vk::binding(5, 0)]] Sampler2DArray samplerShadowMap;
 float textureProj(float4 P, float layer, float2 offset)
 {
 	float shadow = 1.0;
 	float4 shadowCoord = P / P.w;
 	shadowCoord.xy = shadowCoord.xy * 0.5 + 0.5;
 	if (shadowCoord.z > -1.0 && shadowCoord.z < 1.0)
    {
        float dist = samplerShadowMap.Sample(float3(shadowCoord.xy + offset, layer)).r;
 		if (shadowCoord.w > 0.0 && dist < shadowCoord.z)
 		{
 			shadow = SHADOW_FACTOR;
 		}
 	}
 	return shadow;
 }
 float filterPCF(float4 sc, float layer)
 {
    int2 texDim; int elements; int levels;
    samplerShadowMap.GetDimensions(0, texDim.x, texDim.y, elements, levels);
 	float scale = 1.5;
 	float dx = scale * 1.0 / float(texDim.x);
 	float dy = scale * 1.0 / float(texDim.y);
 	float shadowFactor = 0.0;
 	int count = 0;
 	int range = 1;
 	for (int x = -range; x <= range; x++)
 	{
 		for (int y = -range; y <= range; y++)
 		{
 			shadowFactor += textureProj(sc, layer, float2(dx*x, dy*y));
 			count++;
 		}
 	}
 	return shadowFactor / count;
 }
 float3 shadow(float3 fragcolor, float3 fragPos)
 {
 	for (int i = 0; i < LIGHT_COUNT; ++i)
 	{
 		float4 shadowClip = mul(ubo.lights[i].viewMatrix, float4(fragPos.xyz, 1.0));
 		float shadowFactor;
 		#ifdef USE_PCF
 			shadowFactor= filterPCF(shadowClip, i);
 		#else
 			shadowFactor = textureProj(shadowClip, i, float2(0.0, 0.0));
 		#endif
 		fragcolor *= shadowFactor;
 	}
 	return fragcolor;
 }
 [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)
 {
    // Get G-Buffer values
    float3 fragPos = samplerPosition.Sample(input.UV).rgb;
    float3 normal = samplerNormal.Sample(input.UV).rgb;
    float4 albedo = samplerAlbedo.Sample(input.UV);
 	float3 fragcolor;
 	// Debug display
 	if (ubo.displayDebugTarget > 0) {
 		switch (ubo.displayDebugTarget) {
 			case 1: 
 				fragcolor.rgb = shadow(float3(1.0, 1.0, 1.0), fragPos);
 				break;
 			case 2: 
 				fragcolor.rgb = fragPos;
 				break;
 			case 3: 
 				fragcolor.rgb = normal;
 				break;
 			case 4: 
 				fragcolor.rgb = albedo.rgb;
 				break;
 			case 5: 
 				fragcolor.rgb = albedo.aaa;
 				break;
 		}		
 		return float4(fragcolor, 1.0);
 	}
 	// Ambient part
 	fragcolor  = albedo.rgb * AMBIENT_LIGHT;
 	float3 N = normalize(normal);
 	for(int i = 0; i < LIGHT_COUNT; ++i)
 	{
 		// Vector to light
 		float3 L = ubo.lights[i].position.xyz - fragPos;
 		// Distance from light to fragment position
 		float dist = length(L);
 		L = normalize(L);
 		// Viewer to fragment
 		float3 V = ubo.viewPos.xyz - fragPos;
 		V = normalize(V);
 		float lightCosInnerAngle = cos(radians(15.0));
 		float lightCosOuterAngle = cos(radians(25.0));
 		float lightRange = 100.0;
 		// Direction vector from source to target
 		float3 dir = normalize(ubo.lights[i].position.xyz - ubo.lights[i].target.xyz);
 		// Dual cone spot light with smooth transition between inner and outer angle
 		float cosDir = dot(L, dir);
 		float spotEffect = smoothstep(lightCosOuterAngle, lightCosInnerAngle, cosDir);
 		float heightAttenuation = smoothstep(lightRange, 0.0f, dist);
 		// Diffuse lighting
 		float NdotL = max(0.0, dot(N, L));
 		float3 diff = NdotL.xxx;
 		// Specular lighting
 		float3 R = reflect(-L, N);
 		float NdotR = max(0.0, dot(R, V));
 		float3 spec = (pow(NdotR, 16.0) * albedo.a * 2.5).xxx;
 		fragcolor += float3((diff + spec) * spotEffect * heightAttenuation) * ubo.lights[i].color.rgb * albedo.rgb;
 	}
 	// Shadow calculations in a separate pass
 	if (ubo.useShadows > 0)
 	{
 		fragcolor = shadow(fragcolor, fragPos);
 	}
 	return float4(fragcolor, 1);
 }
--- a/shaders/slang/deferredshadows/mrt.slang
+++ b/shaders/slang/deferredshadows/mrt.slang
@ -0,0 +1,83 @@
 /* Copyright (c) 2025, Sascha Willems
 *
 * SPDX-License-Identifier: MIT
 *
 */
 struct VSInput
 {
    float4 Pos;
    float2 UV;
    float3 Color;
    float3 Normal;
    float3 Tangent;
 };
 struct VSOutput
 {
    float4 Pos : SV_POSITION;
    float3 Normal;
    float2 UV;
    float3 Color;
    float3 WorldPos;
    float3 Tangent;
 };
 struct FSOutput
 {
    float4 Position : SV_TARGET0;
    float4 Normal : SV_TARGET1;
    float4 Albedo : SV_TARGET2;
 };
 struct UBO
 {
    float4x4 projection;
    float4x4 model;
    float4x4 view;
    float4 instancePos[3];
 };
 ConstantBuffer<UBO> ubo;
 Sampler2D samplerColor;
 Sampler2D samplerNormalMap;
 [shader("vertex")]
 VSOutput vertexMain(VSInput input, uint InstanceIndex: SV_InstanceID)
 {
    VSOutput output;
    float4 tmpPos = input.Pos + ubo.instancePos[InstanceIndex];
    output.Pos = mul(ubo.projection, mul(ubo.view, mul(ubo.model, tmpPos)));
    output.UV = input.UV;
    // Vertex position in world space
    output.WorldPos = mul(ubo.model, tmpPos).xyz;
    // Normal in world space
    output.Normal = normalize(input.Normal);
    output.Tangent = normalize(input.Tangent);
    // Currently just vertex color
    output.Color = input.Color;
    return output;
 }
 [shader("fragment")]
 FSOutput fragmentMain(VSOutput input)
 {
 	FSOutput output;
 	output.Position = float4(input.WorldPos, 1.0);
 	// Calculate normal in tangent space
 	float3 N = normalize(input.Normal);
 	float3 T = normalize(input.Tangent);
 	float3 B = cross(N, T);
    float3x3 TBN = float3x3(T, B, N);
    float3 tnorm = mul(normalize(samplerNormalMap.Sample(input.UV).xyz * 2.0 - float3(1.0, 1.0, 1.0)), TBN);
 	output.Normal = float4(tnorm, 1.0);
    output.Albedo = samplerColor.Sample(input.UV);
 	return output;
 }
--- a/shaders/slang/deferredshadows/shadow.slang
+++ b/shaders/slang/deferredshadows/shadow.slang
@ -0,0 +1,57 @@
 /* Copyright (c) 2025, Sascha Willems
 *
 * SPDX-License-Identifier: MIT
 *
 */
 #define LIGHT_COUNT 3
 struct VSInput
 {
    float4 Pos;
 }
 struct VSOutput
 {
 	float4 Pos : SV_POSITION;
 	int InstanceIndex;
 };
 struct GSOutput
 {
 	float4 Pos : SV_POSITION;
 	int Layer : SV_RenderTargetArrayIndex;
 };
 struct UBO
 {
    float4x4 mvp[LIGHT_COUNT];
    float4 instancePos[3];
 };
 ConstantBuffer<UBO> ubo;
 [shader("vertex")]
 VSOutput vertexMain(VSInput input, uint InstanceIndex: SV_InstanceID)
 {
    VSOutput output;
    output.InstanceIndex = InstanceIndex;
    output.Pos = input.Pos;
    return output;
 }
 [shader("geometry")]
 [maxvertexcount(3)]
 [instance(3)]
 void geometryMain(triangle VSOutput input[3], uint InvocationID : SV_GSInstanceID, inout TriangleStream<GSOutput> outStream)
 {
 	float4 instancedPos = ubo.instancePos[input[0].InstanceIndex];
 	for (int i = 0; i < 3; i++)
 	{
 		float4 tmpPos = input[i].Pos + instancedPos;
 		GSOutput output;
 		output.Pos = mul(ubo.mvp[InvocationID], tmpPos);
 		output.Layer = InvocationID;
 		outStream.Append( output );
 	}
 	outStream.RestartStrip();
 }