Directional Light + Shadows + Tone Mapping + One Pass Per Light (#2)

2020-10-01 19:46:25 +00:00 · 2020-10-01 19:46:25 +00:00 · 66d4e5bf6e
parent 4095b7eda5
commit 66d4e5bf6e
34 changed files with 1399 additions and 228 deletions
--- a/.gitattributes
+++ b/.gitattributes
@ -0,0 +1 @@
 *.fxb filter=lfs diff=lfs merge=lfs -text
--- a/Cameras/Camera.cs
+++ b/Cameras/Camera.cs
@ -2,22 +2,32 @@ using Microsoft.Xna.Framework;
 namespace Kav
 {
-    public struct Camera
+    public struct PerspectiveCamera
    {
-        public Matrix Transform { get; }
+        public Matrix View { get; }
        public Matrix View
        {
            get
            {
                return Matrix.CreateLookAt(Transform.Translation, Transform.Translation + Transform.Forward, Transform.Up);
            }
        }
        public Matrix Projection { get; }
-        public Camera(Matrix transform, Matrix projection)
+        public Vector3 Position { get; }
        public Vector3 Forward { get; }
        public Vector3 Up { get; }
        public float FieldOfView { get; }
        public float AspectRatio { get; }
        public float NearPlane { get; }
        public float FarPlane { get; }
        public PerspectiveCamera(Vector3 position, Vector3 forward, Vector3 up, float fieldOfView, float aspectRatio, float nearPlane, float farPlane)
        {
-            Transform = transform;
+            Position = position;
-            Projection = projection;
+            Forward = forward;
            Up = up;
            View = Matrix.CreateLookAt(Position, Position + Forward, Up);
            FieldOfView = fieldOfView;
            AspectRatio = aspectRatio;
            NearPlane = nearPlane;
            FarPlane = farPlane;    
            Projection = Matrix.CreatePerspectiveFieldOfView(FieldOfView, AspectRatio, NearPlane, FarPlane);
        }
    }
 }
--- a/EffectInterfaces/DirectionalLightEffect.cs
+++ b/EffectInterfaces/DirectionalLightEffect.cs
@ -1,8 +0,0 @@
 namespace Kav
 {
    public interface DirectionalLightEffect
    {
        int MaxDirectionalLights { get; }
        DirectionalLightCollection DirectionalLights { get; }
    }
 }
--- a/Effects/DeferredPBREffect.cs
+++ b/Effects/DeferredPBREffect.cs
@ -10,15 +10,47 @@ namespace Kav
        EffectParameter gNormalParam;
        EffectParameter gMetallicRoughnessParam;
        EffectParameter shadowMapOneParam;
        EffectParameter shadowMapTwoParam;
        EffectParameter shadowMapThreeParam;
        EffectParameter shadowMapFourParam;
        EffectParameter lightSpaceMatrixOneParam;
        EffectParameter lightSpaceMatrixTwoParam;
        EffectParameter lightSpaceMatrixThreeParam;
        EffectParameter lightSpaceMatrixFourParam;
        EffectParameter viewMatrixParam;
        EffectParameter cascadeFarPlanesParam;
        EffectParameter directionalLightColorParam;
        EffectParameter directionalLightDirectionParam;
        EffectParameter eyePositionParam;
        PointLightCollection pointLightCollection;
        DirectionalLightCollection directionalLightCollection;
        public Texture2D GPosition { get; set; }
        public Texture2D GAlbedo { get; set; }
        public Texture2D GNormal { get; set; }
        public Texture2D GMetallicRoughness { get; set; }
        public Texture2D ShadowMapOne { get; set; }
        public Texture2D ShadowMapTwo { get; set; }
        public Texture2D ShadowMapThree { get; set; }
        public Texture2D ShadowMapFour { get; set; }
        public Matrix LightSpaceMatrixOne { get; set; }
        public Matrix LightSpaceMatrixTwo { get; set; }
        public Matrix LightSpaceMatrixThree { get; set; }
        public Matrix LightSpaceMatrixFour { get; set; }
        public Matrix ViewMatrix { get; set; }
        public readonly float[] CascadeFarPlanes;
        public Vector3 DirectionalLightColor { get; set; }
        public Vector3 DirectionalLightDirection { get; set; }
        public Vector3 EyePosition { get; set; }
        public int MaxPointLights { get; } = 64;
@ -29,16 +61,10 @@ namespace Kav
            private set { pointLightCollection = value; }
        }
        public int MaxDirectionalLights { get; } = 4;
        public DirectionalLightCollection DirectionalLights
        {
            get { return directionalLightCollection; }
            private set { directionalLightCollection = value; }
        }
        public DeferredPBREffect(GraphicsDevice graphicsDevice) : base(graphicsDevice, Resources.DeferredPBREffect)
        {
            CascadeFarPlanes = new float[4];
            CacheEffectParameters();
            pointLightCollection = new PointLightCollection(
@ -46,11 +72,6 @@ namespace Kav
                Parameters["PointLightColors"],
                MaxPointLights
            );
            DirectionalLights = new DirectionalLightCollection(
                Parameters["DirectionalLightDirections"],
                Parameters["DirectionalLightColors"]
            );
        }
        protected DeferredPBREffect(DeferredPBREffect cloneSource) : base(cloneSource)
@ -72,16 +93,6 @@ namespace Kav
            {
                PointLights[i] = cloneSource.PointLights[i];
            }
            DirectionalLights = new DirectionalLightCollection(
                Parameters["DirectionalLightDirections"],
                Parameters["DirectionalLightColors"]
            );
            for (int i = 0; i < MaxDirectionalLights; i++)
            {
                DirectionalLights[i] = cloneSource.DirectionalLights[i];
            }
        }
        public override Effect Clone()
@ -96,17 +107,49 @@ namespace Kav
            gNormalParam.SetValue(GNormal);
            gMetallicRoughnessParam.SetValue(GMetallicRoughness);
            shadowMapOneParam.SetValue(ShadowMapOne);
            shadowMapTwoParam.SetValue(ShadowMapTwo);
            shadowMapThreeParam.SetValue(ShadowMapThree);
            shadowMapFourParam.SetValue(ShadowMapFour);
            lightSpaceMatrixOneParam.SetValue(LightSpaceMatrixOne);
            lightSpaceMatrixTwoParam.SetValue(LightSpaceMatrixTwo);
            lightSpaceMatrixThreeParam.SetValue(LightSpaceMatrixThree);
            lightSpaceMatrixFourParam.SetValue(LightSpaceMatrixFour);
            viewMatrixParam.SetValue(ViewMatrix);
            cascadeFarPlanesParam.SetValue(CascadeFarPlanes);
            directionalLightColorParam.SetValue(DirectionalLightColor);
            directionalLightDirectionParam.SetValue(DirectionalLightDirection);
            eyePositionParam.SetValue(EyePosition);
        }
        void CacheEffectParameters()
        {
-            gPositionParam = Parameters["gPosition"];
+            gPositionParam                 = Parameters["gPosition"];
-            gAlbedoParam = Parameters["gAlbedo"];
+            gAlbedoParam                   = Parameters["gAlbedo"];
-            gNormalParam = Parameters["gNormal"];
+            gNormalParam                   = Parameters["gNormal"];
-            gMetallicRoughnessParam = Parameters["gMetallicRoughness"];
+            gMetallicRoughnessParam        = Parameters["gMetallicRoughness"];
-            eyePositionParam = Parameters["EyePosition"];
+            shadowMapOneParam              = Parameters["shadowMapOne"];
            shadowMapTwoParam              = Parameters["shadowMapTwo"];
            shadowMapThreeParam            = Parameters["shadowMapThree"];
            shadowMapFourParam             = Parameters["shadowMapFour"];
            lightSpaceMatrixOneParam       = Parameters["LightSpaceMatrixOne"];
            lightSpaceMatrixTwoParam       = Parameters["LightSpaceMatrixTwo"];
            lightSpaceMatrixThreeParam     = Parameters["LightSpaceMatrixThree"];
            lightSpaceMatrixFourParam      = Parameters["LightSpaceMatrixFour"];
            viewMatrixParam                = Parameters["ViewMatrix"];
            cascadeFarPlanesParam          = Parameters["CascadeFarPlanes"];
            directionalLightDirectionParam = Parameters["DirectionalLightDirection"];
            directionalLightColorParam     = Parameters["DirectionalLightColor"];
            eyePositionParam               = Parameters["EyePosition"];
        }
    }
 }
--- a/Effects/DeferredPBR_AmbientLightEffect.cs
+++ b/Effects/DeferredPBR_AmbientLightEffect.cs
@ -0,0 +1,31 @@
 using Microsoft.Xna.Framework.Graphics;
 namespace Kav
 {
    public class DeferredPBR_AmbientLightEffect : Effect
    {
        EffectParameter gPositionParam;
        EffectParameter gAlbedoParam;
        public Texture2D GPosition { get; set; }
        public Texture2D GAlbedo { get; set; }
        public DeferredPBR_AmbientLightEffect(GraphicsDevice graphicsDevice) : base(graphicsDevice, Resources.DeferredPBR_AmbientLightEffect)
        {
            CacheEffectParameters();
        }
        protected override void OnApply()
        {
            gPositionParam.SetValue(GPosition);
            gAlbedoParam.SetValue(GAlbedo);
        }
        void CacheEffectParameters()
        {
            gPositionParam                 = Parameters["gPosition"];
            gAlbedoParam                   = Parameters["gAlbedo"];
        }
    }
 }
--- a/Effects/DeferredPBR_DirectionalLightEffect.cs
+++ b/Effects/DeferredPBR_DirectionalLightEffect.cs
@ -0,0 +1,161 @@
 using Microsoft.Xna.Framework;
 using Microsoft.Xna.Framework.Graphics;
 namespace Kav
 {
    public class DeferredPBR_DirectionalLightEffect : Effect
    {
        EffectParameter gPositionParam;
        EffectParameter gAlbedoParam;
        EffectParameter gNormalParam;
        EffectParameter gMetallicRoughnessParam;
        EffectParameter shadowMapOneParam;
        EffectParameter shadowMapTwoParam;
        EffectParameter shadowMapThreeParam;
        EffectParameter shadowMapFourParam;
        EffectParameter eyePositionParam;
        EffectParameter directionalLightColorParam;
        EffectParameter directionalLightDirectionParam;
        EffectParameter cascadeFarPlanesParam;
        EffectParameter shadowMapSizeParam;
        EffectParameter lightSpaceMatrixOneParam;
        EffectParameter lightSpaceMatrixTwoParam;
        EffectParameter lightSpaceMatrixThreeParam;
        EffectParameter lightSpaceMatrixFourParam;
        EffectParameter viewMatrixParam;
        public Texture2D GPosition { get; set; }
        public Texture2D GAlbedo { get; set; }
        public Texture2D GNormal { get; set; }
        public Texture2D GMetallicRoughness { get; set; }
        public Texture2D ShadowMapOne { get; set; }
        public Texture2D ShadowMapTwo { get; set; }
        public Texture2D ShadowMapThree { get; set; }
        public Texture2D ShadowMapFour { get; set; }
        public Vector3 EyePosition { get; set; }
        public Vector3 DirectionalLightDirection { get; set; }
        public Vector3 DirectionalLightColor { get; set; }
        public readonly float[] CascadeFarPlanes;
        public int ShadowMapSize { get; set; }
        public Matrix LightSpaceMatrixOne { get; set; }
        public Matrix LightSpaceMatrixTwo { get; set; }
        public Matrix LightSpaceMatrixThree { get; set; }
        public Matrix LightSpaceMatrixFour { get; set; }
        public Matrix ViewMatrix { get; set; }
        public DeferredPBR_DirectionalLightEffect(GraphicsDevice graphicsDevice) : base(graphicsDevice, Resources.DeferredPBR_DirectionalLightEffect)
        {
            CascadeFarPlanes = new float[4];
            CacheEffectParameters();
        }
        public DeferredPBR_DirectionalLightEffect(DeferredPBR_DirectionalLightEffect cloneSource) : base(cloneSource)
        {
            GPosition = cloneSource.GPosition;
            GAlbedo = cloneSource.GAlbedo;
            GNormal = cloneSource.GNormal;
            GMetallicRoughness = cloneSource.GMetallicRoughness;
            ShadowMapOne = cloneSource.ShadowMapOne;
            ShadowMapTwo = cloneSource.ShadowMapTwo;
            ShadowMapThree = cloneSource.ShadowMapThree;
            ShadowMapFour = cloneSource.ShadowMapFour;
            EyePosition = cloneSource.EyePosition;
            DirectionalLightDirection = cloneSource.DirectionalLightDirection;
            DirectionalLightColor = cloneSource.DirectionalLightColor;
            CascadeFarPlanes = new float[4];
            for (int i = 0 ; i < 4; i++)
            {
                CascadeFarPlanes[i] = cloneSource.CascadeFarPlanes[i];
            }
            ShadowMapSize = cloneSource.ShadowMapSize;
            LightSpaceMatrixOne = cloneSource.LightSpaceMatrixOne;
            LightSpaceMatrixTwo = cloneSource.LightSpaceMatrixTwo;
            LightSpaceMatrixThree = cloneSource.LightSpaceMatrixThree;
            LightSpaceMatrixFour = cloneSource.LightSpaceMatrixFour;
            ViewMatrix = cloneSource.ViewMatrix;
        }
        public override Effect Clone()
        {
            return new DeferredPBR_DirectionalLightEffect(this);
        }
        protected override void OnApply()
        {
            gPositionParam.SetValue(GPosition);
            gAlbedoParam.SetValue(GAlbedo);
            gNormalParam.SetValue(GNormal);
            gMetallicRoughnessParam.SetValue(GMetallicRoughness);
            shadowMapOneParam.SetValue(ShadowMapOne);
            shadowMapTwoParam.SetValue(ShadowMapTwo);
            shadowMapThreeParam.SetValue(ShadowMapThree);
            shadowMapFourParam.SetValue(ShadowMapFour);
            eyePositionParam.SetValue(EyePosition);
            directionalLightDirectionParam.SetValue(DirectionalLightDirection);
            directionalLightColorParam.SetValue(DirectionalLightColor);
            cascadeFarPlanesParam.SetValue(CascadeFarPlanes);
            shadowMapSizeParam.SetValue(ShadowMapSize);
            lightSpaceMatrixOneParam.SetValue(LightSpaceMatrixOne);
            lightSpaceMatrixTwoParam.SetValue(LightSpaceMatrixTwo);
            lightSpaceMatrixThreeParam.SetValue(LightSpaceMatrixThree);
            lightSpaceMatrixFourParam.SetValue(LightSpaceMatrixFour);
            viewMatrixParam.SetValue(ViewMatrix);
        }
        void CacheEffectParameters()
        {
            gPositionParam                 = Parameters["gPosition"];
            gAlbedoParam                   = Parameters["gAlbedo"];
            gNormalParam                   = Parameters["gNormal"];
            gMetallicRoughnessParam        = Parameters["gMetallicRoughness"];
            shadowMapOneParam              = Parameters["shadowMapOne"];
            shadowMapTwoParam              = Parameters["shadowMapTwo"];
            shadowMapThreeParam            = Parameters["shadowMapThree"];
            shadowMapFourParam             = Parameters["shadowMapFour"];
            eyePositionParam               = Parameters["EyePosition"];
            directionalLightDirectionParam = Parameters["DirectionalLightDirection"];
            directionalLightColorParam     = Parameters["DirectionalLightColor"];
            cascadeFarPlanesParam          = Parameters["CascadeFarPlanes"];
            shadowMapSizeParam             = Parameters["ShadowMapSize"];
            lightSpaceMatrixOneParam       = Parameters["LightSpaceMatrixOne"];
            lightSpaceMatrixTwoParam       = Parameters["LightSpaceMatrixTwo"];
            lightSpaceMatrixThreeParam     = Parameters["LightSpaceMatrixThree"];
            lightSpaceMatrixFourParam      = Parameters["LightSpaceMatrixFour"];
            viewMatrixParam                = Parameters["ViewMatrix"];
        }
    }    
 }
--- a/Effects/DeferredPBR_PointLightEffect.cs
+++ b/Effects/DeferredPBR_PointLightEffect.cs
@ -0,0 +1,77 @@
 using Microsoft.Xna.Framework;
 using Microsoft.Xna.Framework.Graphics;
 namespace Kav
 {
    public class DeferredPBR_PointLightEffect : Effect
    {
        EffectParameter gPositionParam;
        EffectParameter gAlbedoParam;
        EffectParameter gNormalParam;
        EffectParameter gMetallicRoughnessParam;
        EffectParameter eyePositionParam;
        EffectParameter pointLightColorParam;
        EffectParameter pointLightPositionParam;
        public Texture2D GPosition { get; set; }
        public Texture2D GAlbedo { get; set; }
        public Texture2D GNormal { get; set; }
        public Texture2D GMetallicRoughness { get; set; }
        public Vector3 EyePosition { get; set; }
        public Vector3 PointLightPosition { get; set; }
        public Vector3 PointLightColor { get; set; }
        public DeferredPBR_PointLightEffect(GraphicsDevice graphicsDevice) : base(graphicsDevice, Resources.DeferredPBR_PointLightEffect)
        {
            CacheEffectParameters();
        }
        public DeferredPBR_PointLightEffect(DeferredPBR_PointLightEffect cloneSource) : base(cloneSource)
        {
            GPosition = cloneSource.GPosition;
            GAlbedo = cloneSource.GAlbedo;
            GNormal = cloneSource.GNormal;
            GMetallicRoughness = cloneSource.GMetallicRoughness;
            EyePosition = cloneSource.EyePosition;
            PointLightPosition = cloneSource.PointLightPosition;
            PointLightColor = cloneSource.PointLightColor;
        }
        public override Effect Clone()
        {
            return new DeferredPBR_PointLightEffect(this);
        }
        protected override void OnApply()
        {
            gPositionParam.SetValue(GPosition);
            gAlbedoParam.SetValue(GAlbedo);
            gNormalParam.SetValue(GNormal);
            gMetallicRoughnessParam.SetValue(GMetallicRoughness);
            eyePositionParam.SetValue(EyePosition);
            pointLightPositionParam.SetValue(PointLightPosition);
            pointLightColorParam.SetValue(PointLightColor);
        }
        void CacheEffectParameters()
        {
            gPositionParam                 = Parameters["gPosition"];
            gAlbedoParam                   = Parameters["gAlbedo"];
            gNormalParam                   = Parameters["gNormal"];
            gMetallicRoughnessParam        = Parameters["gMetallicRoughness"];
            eyePositionParam               = Parameters["EyePosition"];
            pointLightPositionParam        = Parameters["PointLightPosition"];
            pointLightColorParam           = Parameters["PointLightColor"];
        }
    }
 }
--- a/Effects/DirectionalLightCollection.cs
+++ b/Effects/DirectionalLightCollection.cs
@ -1,47 +0,0 @@
 using Microsoft.Xna.Framework;
 using Microsoft.Xna.Framework.Graphics;
 namespace Kav
 {
    public class DirectionalLightCollection
    {
        private readonly Vector3[] directions = new Vector3[4];
        private readonly Vector3[] colors = new Vector3[4];
        private readonly float[] intensities = new float[4];
        readonly EffectParameter lightDirectionsParam;
        readonly EffectParameter lightColorsParam;
        public DirectionalLightCollection(EffectParameter lightDirectionsParam, EffectParameter lightColorsParam)
        {
            this.lightDirectionsParam = lightDirectionsParam;
            this.lightColorsParam = lightColorsParam;
        }
        public DirectionalLight this[int i]
        {
            get
            {
                var color = colors[i] / intensities[i];
                return new DirectionalLight(
                    directions[i],
                    new Color(
                        color.X,
                        color.Y,
                        color.Z,
                        1f
                    ),
                    intensities[i]
                );
            }
            set
            {
                directions[i] = value.Direction;
                colors[i] = value.Color.ToVector3() * value.Intensity;
                intensities[i] = value.Intensity;
                lightDirectionsParam.SetValue(directions);
                lightColorsParam.SetValue(colors);
            }
        }
    }
 }
--- a/Effects/FXB/DeferredPBREffect.fxb
+++ b/Effects/FXB/DeferredPBREffect.fxb
--- a/Effects/FXB/DeferredPBR_AmbientLightEffect.fxb
+++ b/Effects/FXB/DeferredPBR_AmbientLightEffect.fxb
--- a/Effects/FXB/DeferredPBR_DirectionalLightEffect.fxb
+++ b/Effects/FXB/DeferredPBR_DirectionalLightEffect.fxb
--- a/Effects/FXB/DeferredPBR_GBufferEffect.fxb
+++ b/Effects/FXB/DeferredPBR_GBufferEffect.fxb
--- a/Effects/FXB/DeferredPBR_PointLightEffect.fxb
+++ b/Effects/FXB/DeferredPBR_PointLightEffect.fxb
--- a/Effects/FXB/GBufferEffect.fxb
+++ b/Effects/FXB/GBufferEffect.fxb
--- a/Effects/FXB/PBREffect.fxb
+++ b/Effects/FXB/PBREffect.fxb
--- a/Effects/FXB/SimpleDepthEffect.fxb
+++ b/Effects/FXB/SimpleDepthEffect.fxb
--- a/Effects/FXB/ToneMapEffect.fxb
+++ b/Effects/FXB/ToneMapEffect.fxb
--- a/Effects/HLSL/DeferredPBREffect.fx
+++ b/Effects/HLSL/DeferredPBREffect.fx
@ -2,12 +2,16 @@
 static const float PI = 3.141592653589793;
 static const int MAX_POINT_LIGHTS = 64;
-static const int MAX_DIRECTIONAL_LIGHTS = 4;
+static const int NUM_SHADOW_CASCADES = 4;
 DECLARE_TEXTURE(gPosition, 0);
 DECLARE_TEXTURE(gAlbedo, 1);
 DECLARE_TEXTURE(gNormal, 2);
 DECLARE_TEXTURE(gMetallicRoughness, 3);
 DECLARE_TEXTURE(shadowMapOne, 4);
 DECLARE_TEXTURE(shadowMapTwo, 5);
 DECLARE_TEXTURE(shadowMapThree, 6);
 DECLARE_TEXTURE(shadowMapFour, 7);
 BEGIN_CONSTANTS
@ -16,19 +20,45 @@ BEGIN_CONSTANTS
    float3 PointLightPositions[MAX_POINT_LIGHTS]               _ps(c1)      _cb(c1);
    float3 PointLightColors[MAX_POINT_LIGHTS]                  _ps(c65)     _cb(c65);
-    float3 DirectionalLightDirections[MAX_DIRECTIONAL_LIGHTS]  _ps(c129)   _cb(c129);
+    float3 DirectionalLightDirection                           _ps(c129)   _cb(c129);
-    float3 DirectionalLightColors[MAX_DIRECTIONAL_LIGHTS]      _ps(c133)   _cb(c133);
+    float3 DirectionalLightColor                               _ps(c130)   _cb(c130);
    float CascadeFarPlanes[NUM_SHADOW_CASCADES]                _ps(c131)   _cb(c131);
 MATRIX_CONSTANTS
    float4x4 LightSpaceMatrixOne                               _ps(c135)   _cb(c135);
    float4x4 LightSpaceMatrixTwo                               _ps(c139)   _cb(c139);
    float4x4 LightSpaceMatrixThree                             _ps(c143)   _cb(c143);
    float4x4 LightSpaceMatrixFour                              _ps(c147)   _cb(c147);
    // used to select shadow cascade
    float4x4 ViewMatrix                                        _ps(c151)   _cb(c151);
 END_CONSTANTS
 struct VertexInput
 {
    float4 Position : POSITION;
    float2 TexCoord : TEXCOORD;
 };
 struct PixelInput
 {
    float4 Position : SV_POSITION;
    float2 TexCoord : TEXCOORD0;
 };
 PixelInput main_vs(VertexInput input)
 {
    PixelInput output;
    output.Position = input.Position;
    output.TexCoord = input.TexCoord;
    return output;
 }
 // Pixel Shader
 float3 FresnelSchlick(float cosTheta, float3 F0)
@ -71,17 +101,119 @@ float GeometrySmith(float3 N, float3 V, float3 L, float roughness)
    return ggx1 * ggx2;
 }
 float ComputeShadow(float3 positionWorldSpace, float3 N, float L)
 {
    float bias = 0.005 * tan(acos(dot(N, L)));
    bias = clamp(bias, 0, 0.01);
    float4 positionCameraSpace = mul(float4(positionWorldSpace, 1.0), ViewMatrix);
    int shadowCascadeIndex = 0; // 0 is closest
    for (int i = 0; i < NUM_SHADOW_CASCADES; i++)
    {
        if (abs(positionCameraSpace.z) < CascadeFarPlanes[i])
        {
            shadowCascadeIndex = i;
            break;
        }
    }
    float4x4 lightSpaceMatrix;
    if (shadowCascadeIndex == 0)
    {
        lightSpaceMatrix = LightSpaceMatrixOne;
    }
    else if (shadowCascadeIndex == 1)
    {
        lightSpaceMatrix = LightSpaceMatrixTwo;
    }
    else if (shadowCascadeIndex == 2)
    {
        lightSpaceMatrix = LightSpaceMatrixThree;
    }
    else
    {
        lightSpaceMatrix = LightSpaceMatrixFour;
    }
    float4 positionLightSpace = mul(float4(positionWorldSpace, 1.0), lightSpaceMatrix);
    // maps to [-1, 1]
    float3 projectionCoords = positionLightSpace.xyz / positionLightSpace.w;
    // maps to [0, 1]
    projectionCoords.x = (projectionCoords.x * 0.5) + 0.5;
    projectionCoords.y = (projectionCoords.y * 0.5) + 0.5;
    projectionCoords.y *= -1;
    // in XNA clip z is 0 to 1 already
    float inc = 1.0 / 1024.0;
    float shadowFactor = 0;
    for (int row = -1; row <= 1; row++)
    {
        for (int col = -1; col <= 1; col++)
        {
            float closestDepth;
            if (shadowCascadeIndex == 0)
            {
                closestDepth = SAMPLE_TEXTURE(shadowMapOne, projectionCoords.xy + float2(row, col) * inc).r;
            }
            else if (shadowCascadeIndex == 1)
            {
                closestDepth = SAMPLE_TEXTURE(shadowMapTwo, projectionCoords.xy + float2(row, col) * inc).r;
            }
            else if (shadowCascadeIndex == 2)
            {
                closestDepth = SAMPLE_TEXTURE(shadowMapThree, projectionCoords.xy + float2(row, col) * inc).r;
            }
            else
            {
                closestDepth = SAMPLE_TEXTURE(shadowMapFour, projectionCoords.xy + float2(row, col) * inc).r;
            }
            shadowFactor += projectionCoords.z - bias > closestDepth ? 1.0 : 0.0;
        }
    }
    shadowFactor /= 9.0;
    if (projectionCoords.z > 1.0)
    {
        shadowFactor = 1.0;
    }
    return shadowFactor;
    // float currentDepth = projectionCoords.z;
    // if (currentDepth > 1.0)
    // {
    //     return 0.0;
    // }
    // if (currentDepth - bias > closestDepth)
    // {
    //     return 1.0;
    // }
    // else
    // {
    //     return 0.0;
    // }
 }
 float3 ComputeLight(
-    float3 lightDir,
+    float3 L,
    float3 radiance,
    float3 F0,
    float3 V,
    float3 N,
    float3 albedo,
    float metallic,
-    float roughness
+    float roughness,
    float shadow
 ) {
    float3 L = normalize(lightDir);
    float3 H = normalize(V + L);
    float NDF = DistributionGGX(N, H, roughness);
@ -98,7 +230,7 @@ float3 ComputeLight(
    kD *= 1.0 - metallic;
    float NdotL = max(dot(N, L), 0.0);
-    return (kD * albedo / PI + specular) * radiance * NdotL;
+    return (kD * albedo / PI + specular) * radiance * NdotL * shadow;
 }
 float4 ComputeColor(
@ -120,21 +252,20 @@ float4 ComputeColor(
    for (int i = 0; i < MAX_POINT_LIGHTS; i++)
    {
        float3 lightDir = PointLightPositions[i] - worldPosition;
        float3 L = normalize(lightDir);
        float distance = length(lightDir);
        float attenuation = 1.0 / (distance * distance);
        float3 radiance = PointLightColors[i] * attenuation;
-        Lo += ComputeLight(lightDir, radiance, F0, V, N, albedo, metallic, roughness);
+        Lo += ComputeLight(L, radiance, F0, V, N, albedo, metallic, roughness, 1.0);
    }
    // directional light
-    for (int i = 0; i < MAX_DIRECTIONAL_LIGHTS; i++)
+    float3 L = normalize(DirectionalLightDirection);
-    {
+    float3 radiance = DirectionalLightColor;
        float3 lightDir = DirectionalLightDirections[i];
        float3 radiance = DirectionalLightColors[i];
-        Lo += ComputeLight(lightDir, radiance, F0, V, N, albedo, metallic, roughness);
+    float shadow = ComputeShadow(worldPosition, N, L);
-    }
+    Lo += ComputeLight(L, radiance, F0, V, N, albedo, metallic, roughness, (1.0 - shadow));
    float3 ambient = float3(0.03, 0.03, 0.03) * albedo; // * AO;
    float3 color = ambient + Lo;
@ -148,13 +279,13 @@ float4 ComputeColor(
 float4 main_ps(PixelInput input) : SV_TARGET0
 {
-    float3 fragPosition = SAMPLE_TEXTURE(gPosition, input.TexCoord).rgb;
+    float3 worldPosition = SAMPLE_TEXTURE(gPosition, input.TexCoord).rgb;
    float3 normal = SAMPLE_TEXTURE(gNormal, input.TexCoord).xyz;
    float3 albedo = SAMPLE_TEXTURE(gAlbedo, input.TexCoord).rgb;
    float2 metallicRoughness = SAMPLE_TEXTURE(gMetallicRoughness, input.TexCoord).rg;
    return ComputeColor(
-        fragPosition,
+        worldPosition,
        normal,
        albedo,
        metallicRoughness.r,
@ -166,6 +297,7 @@ Technique DeferredPBR
 {
    Pass
    {
        VertexShader = compile vs_3_0 main_vs();
        PixelShader = compile ps_3_0 main_ps();
    }
 }
--- a/Effects/HLSL/DeferredPBR_AmbientLightEffect.fx
+++ b/Effects/HLSL/DeferredPBR_AmbientLightEffect.fx
@ -0,0 +1,54 @@
 #include "Macros.fxh" // from FNA
 DECLARE_TEXTURE(gPosition, 0);
 DECLARE_TEXTURE(gAlbedo, 1);
 struct VertexInput
 {
    float4 Position : POSITION;
    float2 TexCoord : TEXCOORD;
 };
 struct PixelInput
 {
    float4 Position : SV_POSITION;
    float2 TexCoord : TEXCOORD0;
 };
 PixelInput main_vs(VertexInput input)
 {
    PixelInput output;
    output.Position = input.Position;
    output.TexCoord = input.TexCoord;
    return output;
 }
 float4 ComputeColor(
    float3 worldPosition,
    float3 albedo
 ) {
    float3 color = float3(0.03, 0.03, 0.03) * albedo;
    return float4(color, 1.0);
 }
 float4 main_ps(PixelInput input) : SV_TARGET0
 {
    float3 worldPosition = SAMPLE_TEXTURE(gPosition, input.TexCoord).rgb;
    float3 albedo = SAMPLE_TEXTURE(gAlbedo, input.TexCoord).rgb;
    return ComputeColor(
        worldPosition,
        albedo
    );
 }
 Technique DeferredPBR_Ambient
 {
    Pass
    {
        VertexShader = compile vs_3_0 main_vs();
        PixelShader = compile ps_3_0 main_ps();
    }
 }
--- a/Effects/HLSL/DeferredPBR_DirectionalLightEffect.fx
+++ b/Effects/HLSL/DeferredPBR_DirectionalLightEffect.fx
@ -0,0 +1,252 @@
 #include "Macros.fxh" //from FNA
 #include "Lighting.fxh"
 static const int NUM_SHADOW_CASCADES = 4;
 DECLARE_TEXTURE(gPosition, 0);
 DECLARE_TEXTURE(gAlbedo, 1);
 DECLARE_TEXTURE(gNormal, 2);
 DECLARE_TEXTURE(gMetallicRoughness, 3);
 DECLARE_TEXTURE(shadowMapOne, 4);
 DECLARE_TEXTURE(shadowMapTwo, 5);
 DECLARE_TEXTURE(shadowMapThree, 6);
 DECLARE_TEXTURE(shadowMapFour, 7);
 BEGIN_CONSTANTS
    float3 EyePosition                                         _ps(c0)    _cb(c0);
    float3 DirectionalLightDirection                           _ps(c1)    _cb(c1);
    float3 DirectionalLightColor                               _ps(c2)    _cb(c2);
    float CascadeFarPlanes[NUM_SHADOW_CASCADES]                _ps(c3)    _cb(c3);
    float ShadowMapSize                                        _ps(c7)    _cb(c7);
 MATRIX_CONSTANTS
    float4x4 LightSpaceMatrixOne                               _ps(c8)    _cb(c8);
    float4x4 LightSpaceMatrixTwo                               _ps(c12)   _cb(c12);
    float4x4 LightSpaceMatrixThree                             _ps(c16)   _cb(c16);
    float4x4 LightSpaceMatrixFour                              _ps(c20)   _cb(c20);
    // used to select shadow cascade
    float4x4 ViewMatrix                                        _ps(c24)   _cb(c24);
 END_CONSTANTS
 static float2 poissonDisk[16] = 
 {
   float2( -0.94201624, -0.39906216 ), 
   float2( 0.94558609, -0.76890725 ), 
   float2( -0.094184101, -0.92938870 ), 
   float2( 0.34495938, 0.29387760 ), 
   float2( -0.91588581, 0.45771432 ), 
   float2( -0.81544232, -0.87912464 ), 
   float2( -0.38277543, 0.27676845 ), 
   float2( 0.97484398, 0.75648379 ), 
   float2( 0.44323325, -0.97511554 ), 
   float2( 0.53742981, -0.47373420 ), 
   float2( -0.26496911, -0.41893023 ), 
   float2( 0.79197514, 0.19090188 ), 
   float2( -0.24188840, 0.99706507 ), 
   float2( -0.81409955, 0.91437590 ), 
   float2( 0.19984126, 0.78641367 ), 
   float2( 0.14383161, -0.14100790 ) 
 };
 struct VertexInput
 {
    float4 Position : POSITION;
    float2 TexCoord : TEXCOORD;
 };
 struct PixelInput
 {
    float4 Position : SV_POSITION;
    float2 TexCoord : TEXCOORD0;
 };
 PixelInput main_vs(VertexInput input)
 {
    PixelInput output;
    output.Position = input.Position;
    output.TexCoord = input.TexCoord;
    return output;
 }
 // Pixel Shader
 // Returns a random number based on a vec3 and an int.
 float random(float3 seed, int i){
 	float4 seed4 = float4(seed, i);
 	float dot_product = dot(seed4, float4(12.9898,78.233,45.164,94.673));
 	return frac(sin(dot_product) * 43758.5453);
 }
 float PoissonCoord(sampler shadowMap, float3 worldPosition, float2 texCoord, float fragmentDepth, float bias)
 {
    float visibility = 1.0;
    for (int i = 0; i < 16; i++)
    {
        int index = int(16.0 * random(floor(worldPosition * 1000.0), i)) % 16;
        if (tex2D(shadowMap, texCoord + poissonDisk[index] / 1024.0).r < fragmentDepth - bias)
        {
            visibility -= 0.05;
        }
    }
    return visibility;
 }
 float ComputeShadow(float3 positionWorldSpace, float3 N, float3 L)
 {
    float bias = 0.005 * tan(acos(dot(N, L)));
    bias = clamp(bias, 0, 0.01);
    float4 positionCameraSpace = mul(float4(positionWorldSpace, 1.0), ViewMatrix);
    int shadowCascadeIndex = 0; // 0 is closest
    for (int i = 0; i < NUM_SHADOW_CASCADES; i++)
    {
        if (abs(positionCameraSpace.z) < CascadeFarPlanes[i])
        {
            shadowCascadeIndex = i;
            break;
        }
    }
    float4x4 lightSpaceMatrix;
    if (shadowCascadeIndex == 0)
    {
        lightSpaceMatrix = LightSpaceMatrixOne;
    }
    else if (shadowCascadeIndex == 1)
    {
        lightSpaceMatrix = LightSpaceMatrixTwo;
    }
    else if (shadowCascadeIndex == 2)
    {
        lightSpaceMatrix = LightSpaceMatrixThree;
    }
    else
    {
        lightSpaceMatrix = LightSpaceMatrixFour;
    }
    float4 positionLightSpace = mul(float4(positionWorldSpace, 1.0), lightSpaceMatrix);
    // maps to [-1, 1]
    float3 projectionCoords = positionLightSpace.xyz / positionLightSpace.w;
    // maps to [0, 1]
    projectionCoords.x = (projectionCoords.x * 0.5) + 0.5;
    projectionCoords.y = (projectionCoords.y * 0.5) + 0.5;
    projectionCoords.y *= -1;
    // in XNA clip z is 0 to 1 already
    if (projectionCoords.z > 1.0)
    {
        return 1.0;
    }
    float inc = 1.0 / ShadowMapSize; // TODO: shadow map size uniform
    // PCF + Poisson soft shadows
    float visibility = 0.0;
    // for (int row = -1; row <= 1; row++)
    // {
    //     for (int col = -1; col <= 1; col++)
    //     {
    //         if (shadowCascadeIndex == 0)
    //         {
    //             visibility += PoissonCoord(SAMPLER(shadowMapOne), positionWorldSpace, projectionCoords.xy + float2(row, col) * inc, projectionCoords.z, bias);
    //         }
    //         else if (shadowCascadeIndex == 1)
    //         {
    //             visibility += PoissonCoord(SAMPLER(shadowMapTwo), positionWorldSpace, projectionCoords.xy + float2(row, col) * inc, projectionCoords.z, bias);
    //         }
    //         else if (shadowCascadeIndex == 2)
    //         {
    //             visibility += PoissonCoord(SAMPLER(shadowMapThree), positionWorldSpace, projectionCoords.xy + float2(row, col) * inc, projectionCoords.z, bias);
    //         }
    //         else
    //         {
    //             visibility += PoissonCoord(SAMPLER(shadowMapFour), positionWorldSpace, projectionCoords.xy + float2(row, col) * inc, projectionCoords.z, bias);
    //         }
    //     }
    // }
    // visibility /= 9.0;
    if (shadowCascadeIndex == 0)
    {
        visibility = PoissonCoord(SAMPLER(shadowMapOne), positionWorldSpace, projectionCoords.xy, projectionCoords.z, bias);
    }
    else if (shadowCascadeIndex == 1)
    {
        visibility = PoissonCoord(SAMPLER(shadowMapTwo), positionWorldSpace, projectionCoords.xy, projectionCoords.z, bias);
    }
    else if (shadowCascadeIndex == 2)
    {
        visibility = PoissonCoord(SAMPLER(shadowMapThree), positionWorldSpace, projectionCoords.xy, projectionCoords.z, bias);
    }
    else
    {
        visibility = PoissonCoord(SAMPLER(shadowMapFour), positionWorldSpace, projectionCoords.xy, projectionCoords.z, bias);
    }
    return visibility;
 }
 float4 ComputeColor(
    float3 worldPosition,
    float3 worldNormal,
    float3 albedo,
    float metallic,
    float roughness
 ) {
    float3 V = normalize(EyePosition - worldPosition);
    float3 N = normalize(worldNormal);
    float3 F0 = float3(0.04, 0.04, 0.04);
    F0 = lerp(F0, albedo, metallic);
    float3 L = normalize(DirectionalLightDirection);
    float3 radiance = DirectionalLightColor;
    float shadow = ComputeShadow(worldPosition, N, L);
    float3 color = ComputeLight(L, radiance, F0, V, N, albedo, metallic, roughness, shadow);
    return float4(color, 1.0);
 }
 float4 main_ps(PixelInput input) : SV_TARGET0
 {
    float3 worldPosition = SAMPLE_TEXTURE(gPosition, input.TexCoord).rgb;
    float3 normal = SAMPLE_TEXTURE(gNormal, input.TexCoord).xyz;
    float3 albedo = SAMPLE_TEXTURE(gAlbedo, input.TexCoord).rgb;
    float2 metallicRoughness = SAMPLE_TEXTURE(gMetallicRoughness, input.TexCoord).rg;
    return ComputeColor(
        worldPosition,
        normal,
        albedo,
        metallicRoughness.r,
        metallicRoughness.g
    );
 }
 Technique DeferredPBR_Directional
 {
    Pass
    {
        VertexShader = compile vs_3_0 main_vs();
        PixelShader = compile ps_3_0 main_ps();
    }
 }
--- a/Effects/HLSL/DeferredPBR_GBufferEffect.fx
+++ b/Effects/HLSL/DeferredPBR_GBufferEffect.fx
@ -79,10 +79,10 @@ PixelOutput NonePS(PixelInput input)
 {
    PixelOutput output;
-    output.gPosition = float4(input.PositionWorld, 0.0);
+    output.gPosition = float4(input.PositionWorld, 1.0);
-    output.gNormal = float4(normalize(input.NormalWorld), 0.0);
+    output.gNormal = float4(normalize(input.NormalWorld), 1.0);
    output.gAlbedo = float4(AlbedoValue, 1.0);
-    output.gMetallicRoughness = float4(MetallicValue, RoughnessValue, 0.0, 0.0);
+    output.gMetallicRoughness = float4(MetallicValue, RoughnessValue, 0.0, 1.0);
    return output;
 }
@ -91,10 +91,10 @@ PixelOutput AlbedoPS(PixelInput input)
 {
    PixelOutput output;
-    output.gPosition = float4(input.PositionWorld, 0.0);
+    output.gPosition = float4(input.PositionWorld, 1.0);
-    output.gNormal = float4(normalize(input.NormalWorld), 0.0);
+    output.gNormal = float4(normalize(input.NormalWorld), 1.0);
    output.gAlbedo = SAMPLE_TEXTURE(AlbedoTexture, input.TexCoord);
-    output.gMetallicRoughness = float4(MetallicValue, RoughnessValue, 0.0, 0.0);
+    output.gMetallicRoughness = float4(MetallicValue, RoughnessValue, 0.0, 1.0);
    return output;
 }
@ -103,8 +103,8 @@ PixelOutput MetallicRoughnessPS(PixelInput input)
 {
    PixelOutput output;
-    output.gPosition = float4(input.PositionWorld, 0.0);
+    output.gPosition = float4(input.PositionWorld, 1.0);
-    output.gNormal = float4(normalize(input.NormalWorld), 0.0);
+    output.gNormal = float4(normalize(input.NormalWorld), 1.0);
    output.gAlbedo = float4(AlbedoValue, 1.0);
    output.gMetallicRoughness = SAMPLE_TEXTURE(MetallicRoughnessTexture, input.TexCoord);
@ -115,10 +115,10 @@ PixelOutput NormalPS(PixelInput input)
 {
    PixelOutput output;
-    output.gPosition = float4(input.PositionWorld, 0.0);
+    output.gPosition = float4(input.PositionWorld, 1.0);
-    output.gNormal = float4(GetNormalFromMap(input.PositionWorld, input.TexCoord, input.NormalWorld), 0.0);
+    output.gNormal = float4(GetNormalFromMap(input.PositionWorld, input.TexCoord, input.NormalWorld), 1.0);
    output.gAlbedo = float4(AlbedoValue, 1.0);
-    output.gMetallicRoughness = float4(MetallicValue, RoughnessValue, 0.0, 0.0);
+    output.gMetallicRoughness = float4(MetallicValue, RoughnessValue, 0.0, 1.0);
    return output;
 }
@ -127,8 +127,8 @@ PixelOutput AlbedoMetallicRoughnessPS(PixelInput input)
 {
    PixelOutput output;
-    output.gPosition = float4(input.PositionWorld, 0.0);
+    output.gPosition = float4(input.PositionWorld, 1.0);
-    output.gNormal = float4(normalize(input.NormalWorld), 0.0);
+    output.gNormal = float4(normalize(input.NormalWorld), 1.0);
    output.gAlbedo = SAMPLE_TEXTURE(AlbedoTexture, input.TexCoord);
    output.gMetallicRoughness = SAMPLE_TEXTURE(MetallicRoughnessTexture, input.TexCoord);
@ -139,10 +139,10 @@ PixelOutput AlbedoNormalPS(PixelInput input)
 {
    PixelOutput output;
-    output.gPosition = float4(input.PositionWorld, 0.0);
+    output.gPosition = float4(input.PositionWorld, 1.0);
-    output.gNormal = float4(GetNormalFromMap(input.PositionWorld, input.TexCoord, input.NormalWorld), 0.0);
+    output.gNormal = float4(GetNormalFromMap(input.PositionWorld, input.TexCoord, input.NormalWorld), 1.0);
    output.gAlbedo = SAMPLE_TEXTURE(AlbedoTexture, input.TexCoord);
-    output.gMetallicRoughness = float4(MetallicValue, RoughnessValue, 0.0, 0.0);
+    output.gMetallicRoughness = float4(MetallicValue, RoughnessValue, 0.0, 1.0);
    return output;
 }
@ -151,8 +151,8 @@ PixelOutput MetallicRoughnessNormalPS(PixelInput input)
 {
    PixelOutput output;
-    output.gPosition = float4(input.PositionWorld, 0.0);
+    output.gPosition = float4(input.PositionWorld, 1.0);
-    output.gNormal = float4(GetNormalFromMap(input.PositionWorld, input.TexCoord, input.NormalWorld), 0.0);
+    output.gNormal = float4(GetNormalFromMap(input.PositionWorld, input.TexCoord, input.NormalWorld), 1.0);
    output.gAlbedo = float4(AlbedoValue, 1.0);
    output.gMetallicRoughness = SAMPLE_TEXTURE(MetallicRoughnessTexture, input.TexCoord);
@ -163,8 +163,8 @@ PixelOutput AlbedoMetallicRoughnessNormalMapPS(PixelInput input)
 {
    PixelOutput output;
-    output.gPosition = float4(input.PositionWorld, 0.0);
+    output.gPosition = float4(input.PositionWorld, 1.0);
-    output.gNormal = float4(GetNormalFromMap(input.PositionWorld, input.TexCoord, input.NormalWorld), 0.0);
+    output.gNormal = float4(GetNormalFromMap(input.PositionWorld, input.TexCoord, input.NormalWorld), 1.0);
    output.gAlbedo = SAMPLE_TEXTURE(AlbedoTexture, input.TexCoord);
    output.gMetallicRoughness = SAMPLE_TEXTURE(MetallicRoughnessTexture, input.TexCoord);
--- a/Effects/HLSL/DeferredPBR_PointLightEffect.fx
+++ b/Effects/HLSL/DeferredPBR_PointLightEffect.fx
@ -0,0 +1,91 @@
 #include "Macros.fxh" //from FNA
 #include "Lighting.fxh" 
 DECLARE_TEXTURE(gPosition, 0);
 DECLARE_TEXTURE(gAlbedo, 1);
 DECLARE_TEXTURE(gNormal, 2);
 DECLARE_TEXTURE(gMetallicRoughness, 3);
 BEGIN_CONSTANTS
    float3 EyePosition                      _ps(c0)     _cb(c0);
    float3 PointLightPosition               _ps(c1)     _cb(c1);
    float3 PointLightColor                  _ps(c2)     _cb(c2);
 MATRIX_CONSTANTS
 END_CONSTANTS
 struct VertexInput
 {
    float4 Position : POSITION;
    float2 TexCoord : TEXCOORD;
 };
 struct PixelInput
 {
    float4 Position : SV_POSITION;
    float2 TexCoord : TEXCOORD0;
 };
 PixelInput main_vs(VertexInput input)
 {
    PixelInput output;
    output.Position = input.Position;
    output.TexCoord = input.TexCoord;
    return output;
 }
 // Pixel Shader
 float4 ComputeColor(
    float3 worldPosition,
    float3 worldNormal,
    float3 albedo,
    float metallic,
    float roughness
 ) {
    float3 V = normalize(EyePosition - worldPosition);
    float3 N = normalize(worldNormal);
    float3 F0 = float3(0.04, 0.04, 0.04);
    F0 = lerp(F0, albedo, metallic);
    float3 lightDir = PointLightPosition - worldPosition;
    float3 L = normalize(lightDir);
    float distance = length(lightDir);
    float attenuation = 1.0 / (distance * distance);
    float3 radiance = PointLightColor * attenuation;
    float3 color = ComputeLight(L, radiance, F0, V, N, albedo, metallic, roughness, 1.0);
    return float4(color, 1.0);
 }
 float4 main_ps(PixelInput input) : SV_TARGET0
 {
    float3 worldPosition = SAMPLE_TEXTURE(gPosition, input.TexCoord).rgb;
    float3 normal = SAMPLE_TEXTURE(gNormal, input.TexCoord).xyz;
    float3 albedo = SAMPLE_TEXTURE(gAlbedo, input.TexCoord).rgb;
    float2 metallicRoughness = SAMPLE_TEXTURE(gMetallicRoughness, input.TexCoord).rg;
    return ComputeColor(
        worldPosition,
        normal,
        albedo,
        metallicRoughness.r,
        metallicRoughness.g
    );
 }
 Technique DeferredPBR_Point
 {
    Pass
    {
        VertexShader = compile vs_3_0 main_vs();
        PixelShader = compile ps_3_0 main_ps();
    }
 }
--- a/Effects/HLSL/Lighting.fxh
+++ b/Effects/HLSL/Lighting.fxh
@ -0,0 +1,71 @@
 static const float PI = 3.141592653589793;
 float3 FresnelSchlick(float cosTheta, float3 F0)
 {
    return F0 + (1.0 - F0) * pow(1.0 - cosTheta, 5.0);
 }
 float DistributionGGX(float3 N, float3 H, float roughness)
 {
    float a = roughness * roughness;
    float a2 = a * a;
    float NdotH = max(dot(N, H), 0.0);
    float NdotH2 = NdotH * NdotH;
    float num = a2;
    float denom = (NdotH2 * (a2 - 1.0) + 1.0);
    denom = PI * denom * denom;
    return num / denom;
 }
 float GeometrySchlickGGX(float NdotV, float roughness)
 {
    float r = (roughness + 1.0);
    float k = (r * r) / 8.0;
    float num = NdotV;
    float denom = NdotV * (1.0 - k) + k;
    return num / denom;
 }
 float GeometrySmith(float3 N, float3 V, float3 L, float roughness)
 {
    float NdotV = max(dot(N, V), 0.0);
    float NdotL = max(dot(N, L), 0.0);
    float ggx2 = GeometrySchlickGGX(NdotV, roughness);
    float ggx1 = GeometrySchlickGGX(NdotL, roughness);
    return ggx1 * ggx2;
 }
 float3 ComputeLight(
    float3 L,
    float3 radiance,
    float3 F0,
    float3 V,
    float3 N,
    float3 albedo,
    float metallic,
    float roughness,
    float visibility
 ) {
    float3 H = normalize(V + L);
    float NDF = DistributionGGX(N, H, roughness);
    float G = GeometrySmith(N, V, L, roughness);
    float3 F = FresnelSchlick(max(dot(H, V), 0.0), F0);
    float3 numerator = NDF * G * F;
    float denominator = 4.0 * max(dot(N, V), 0.0) * max(dot(N, L), 0.0);
    float3 specular = numerator / max(denominator, 0.001);
    float3 kS = F;
    float3 kD = float3(1.0, 1.0, 1.0) - kS;
    kD *= 1.0 - metallic;
    float NdotL = max(dot(N, L), 0.0);
    return (kD * albedo / PI + specular) * radiance * NdotL * visibility;
 }
--- a/Effects/HLSL/Macros.fxh
+++ b/Effects/HLSL/Macros.fxh
@ -54,4 +54,5 @@
 #define SAMPLE_TEXTURE(Name, texCoord)  tex2D(Name##Sampler, texCoord)
 #define SAMPLE_CUBEMAP(Name, texCoord)  texCUBE(Name##Sampler, texCoord)
 #define SAMPLE_CUBEMAP_LOD(Name, texCoord)  texCUBElod(Name##Sampler, texCoord)
 #define SAMPLER(Name) Name##Sampler
 #endif
--- a/Effects/HLSL/SimpleDepthEffect.fx
+++ b/Effects/HLSL/SimpleDepthEffect.fx
@ -16,21 +16,29 @@ struct VertexShaderInput
 struct VertexShaderOutput
 {
    float4 Position : SV_Position;
    float Depth : TEXCOORD0;
 };
 VertexShaderOutput main_vs(VertexShaderInput input)
 {
    VertexShaderOutput output;
-    output.Position = mul(float4(input.Position.xyz, 1.0), ModelViewProjection);
+    output.Position = mul(input.Position, ModelViewProjection);
    output.Depth = output.Position.z;
    return output;
 }
 float4 main_ps(VertexShaderOutput input) : SV_TARGET0
 {
    return float4(input.Depth, 0.0, 0.0, 0.0);
 }
 Technique SimpleDepth
 {
    Pass
    {
        VertexShader = compile vs_3_0 main_vs();
        PixelShader  = compile ps_3_0 main_ps();
    }
 }
--- a/Effects/HLSL/ToneMapEffect.fx
+++ b/Effects/HLSL/ToneMapEffect.fx
@ -0,0 +1,20 @@
 sampler TextureSampler : register(s0);
 float4 main_ps(float2 texCoord : TEXCOORD0) : COLOR0
 {
    float3 color = tex2D(TextureSampler, texCoord).xyz;
    color = color / (color + float3(1.0, 1.0, 1.0));
    float exposureConstant = 1.0 / 2.2;
    color = pow(color, float3(exposureConstant, exposureConstant, exposureConstant));
    return float4(color, 1.0);
 }
 Technique DeferredPBR
 {
    Pass
    {
        PixelShader = compile ps_3_0 main_ps();
    }
 }
--- a/Effects/PBREffect.cs
+++ b/Effects/PBREffect.cs
@ -3,7 +3,7 @@ using Microsoft.Xna.Framework.Graphics;
 namespace Kav
 {
-    public class PBREffect : Effect, TransformEffect, PointLightEffect, DirectionalLightEffect
+    public class PBREffect : Effect, TransformEffect, PointLightEffect
    {
        EffectParameter worldParam;
        EffectParameter worldViewProjectionParam;
@ -31,7 +31,6 @@ namespace Kav
        Matrix view = Matrix.Identity;
        Matrix projection = Matrix.Identity;
        PointLightCollection pointLightCollection;
        DirectionalLightCollection directionalLightCollection;
        Vector3 albedo;
        float metallic;
@ -84,14 +83,6 @@ namespace Kav
            private set { pointLightCollection = value; }
        }
        public int MaxDirectionalLights { get; } = 4;
        public DirectionalLightCollection DirectionalLights
        {
            get { return directionalLightCollection; }
            private set { directionalLightCollection = value; }
        }
        public Vector3 Albedo
        {
            get { return albedo; }
@ -204,11 +195,6 @@ namespace Kav
                Parameters["PositionLightColors"],
                MaxPointLights
            );
            directionalLightCollection = new DirectionalLightCollection(
                Parameters["LightDirections"],
                Parameters["DirectionLightColors"]
            );
        }
        protected PBREffect(PBREffect cloneSource) : base(cloneSource)
@ -230,16 +216,6 @@ namespace Kav
                PointLights[i] = cloneSource.PointLights[i];
            }
            DirectionalLights = new DirectionalLightCollection(
                Parameters["LightDirections"],
                Parameters["DirectionLightColors"]
            );
            for (int i = 0; i < MaxDirectionalLights; i++)
            {
                DirectionalLights[i] = cloneSource.DirectionalLights[i];
            }
            AlbedoTexture = cloneSource.AlbedoTexture;
            NormalTexture = cloneSource.NormalTexture;
            EmissionTexture = cloneSource.EmissionTexture;
--- a/Effects/SimpleDepthEffect.cs
+++ b/Effects/SimpleDepthEffect.cs
@ -42,6 +42,7 @@ namespace Kav
                dirtyFlags |= EffectDirtyFlags.WorldViewProj;
            }
        }
        public SimpleDepthEffect(GraphicsDevice graphicsDevice) : base(graphicsDevice, Resources.SimpleDepthEffect)
        {
            CacheEffectParameters();
@ -51,8 +52,8 @@ namespace Kav
        {
            if ((dirtyFlags & EffectDirtyFlags.WorldViewProj) != 0)
            {
-                Matrix.Multiply(ref model, ref view, out Matrix modelView);
+                Matrix.Multiply(ref view, ref projection, out Matrix viewProjection);
-                Matrix.Multiply(ref modelView, ref projection, out Matrix worldViewProj);
+                Matrix.Multiply(ref model, ref viewProjection, out Matrix worldViewProj);
                modelViewProjectionParam.SetValue(worldViewProj);
--- a/Kav.Core.csproj
+++ b/Kav.Core.csproj
@ -15,9 +15,21 @@
  </ItemGroup>
  <ItemGroup>
    <EmbeddedResource Include="Effects\FXB\DeferredPBR_AmbientLightEffect.fxb">
      <LogicalName>Kav.Resources.DeferredPBR_AmbientLightEffect.fxb</LogicalName>
    </EmbeddedResource>
    <EmbeddedResource Include="Effects\FXB\DeferredPBR_PointLightEffect.fxb">
      <LogicalName>Kav.Resources.DeferredPBR_PointLightEffect.fxb</LogicalName>
    </EmbeddedResource>
    <EmbeddedResource Include="Effects\FXB\DeferredPBR_DirectionalLightEffect.fxb">
      <LogicalName>Kav.Resources.DeferredPBR_DirectionalLightEffect.fxb</LogicalName>
    </EmbeddedResource>
    <EmbeddedResource Include="Effects\FXB\DeferredPBR_GBufferEffect.fxb">
      <LogicalName>Kav.Resources.DeferredPBR_GBufferEffect.fxb</LogicalName>
    </EmbeddedResource>
    <EmbeddedResource Include="Effects\FXB\ToneMapEffect.fxb">
      <LogicalName>Kav.Resources.ToneMapEffect.fxb</LogicalName>
    </EmbeddedResource>
    <EmbeddedResource Include="Effects\FXB\DeferredPBREffect.fxb">
      <LogicalName>Kav.Resources.DeferredPBREffect.fxb</LogicalName>
    </EmbeddedResource>
--- a/Kav.Framework.csproj
+++ b/Kav.Framework.csproj
@ -15,9 +15,21 @@
  </ItemGroup>
  <ItemGroup>
    <EmbeddedResource Include="Effects\FXB\DeferredPBR_AmbientLightEffect.fxb">
      <LogicalName>Kav.Resources.DeferredPBR_AmbientLightEffect.fxb</LogicalName>
    </EmbeddedResource>
    <EmbeddedResource Include="Effects\FXB\DeferredPBR_PointLightEffect.fxb">
      <LogicalName>Kav.Resources.DeferredPBR_PointLightEffect.fxb</LogicalName>
    </EmbeddedResource>
    <EmbeddedResource Include="Effects\FXB\DeferredPBR_DirectionalLightEffect.fxb">
      <LogicalName>Kav.Resources.DeferredPBR_DirectionalLightEffect.fxb</LogicalName>
    </EmbeddedResource>
    <EmbeddedResource Include="Effects\FXB\DeferredPBR_GBufferEffect.fxb">
      <LogicalName>Kav.Resources.DeferredPBR_GBufferEffect.fxb</LogicalName>
    </EmbeddedResource>
    <EmbeddedResource Include="Effects\FXB\ToneMapEffect.fxb">
      <LogicalName>Kav.Resources.ToneMapEffect.fxb</LogicalName>
    </EmbeddedResource>
    <EmbeddedResource Include="Effects\FXB\DeferredPBREffect.fxb">
      <LogicalName>Kav.Resources.DeferredPBREffect.fxb</LogicalName>
    </EmbeddedResource>
--- a/Lights/DirectionalLight.cs
+++ b/Lights/DirectionalLight.cs
@ -12,7 +12,7 @@ namespace Kav
        {
            get
            {
-                return Matrix.CreateLookAt(-Direction * 100f, Vector3.Zero, Vector3.Up);
+                return Matrix.CreateLookAt(Direction * 100f, Vector3.Zero, Vector3.Up);
            }
        }
--- a/README.md
+++ b/README.md
@ -0,0 +1,29 @@
 # Kav
 A 3D renderer built on top of FNA.
 ## Roadmap
 Essential
 - [x] PBR shading
 - [x] Deferred rendering
 - [x] Point lighting
 - [x] Directional lighting
 - [x] Directional shadow maps
 - [x] Cascading shadow maps
 - [x] Tone map shader
 - [x] Poisson soft shadowing
 - [ ] Frustum culling
 - [ ] Shadow-casting point lights
 - [ ] Parabolic lights
 - [ ] Skyboxes
 - [ ] Screen-space reflection
 Nice-To-Haves
 - [ ] Anti-aliasing
 - [ ] Image-based lighting
 - [ ] Volumetric lighting
 - [ ] Volumetric smoke
 - [ ] 
--- a/Renderer.cs
+++ b/Renderer.cs
@ -6,38 +6,84 @@ namespace Kav
 {
    public class Renderer
    {
        private const int MAX_SHADOW_CASCADES = 4;
        private int ShadowMapSize { get; }
        private GraphicsDevice GraphicsDevice { get; }
        private int RenderDimensionsX { get; }
        private int RenderDimensionsY { get; }
-        private RenderTarget2D DepthRenderTarget { get; }
+        private VertexBuffer FullscreenTriangle { get; }
        private int NumShadowCascades { get; }
        private RenderTarget2D ColorRenderTarget { get; }
        private RenderTarget2D DirectionalRenderTarget { get; }
        private RenderTarget2D[] ShadowRenderTargets { get; }
        private DeferredPBREffect DeferredPBREffect { get; }
        private DeferredPBR_AmbientLightEffect DeferredAmbientLightEffect { get; }
        private DeferredPBR_PointLightEffect DeferredPointLightEffect { get; }
        private DeferredPBR_DirectionalLightEffect DeferredDirectionalLightEffect { get; }
        private SimpleDepthEffect SimpleDepthEffect { get; }
        private Effect ToneMapEffect { get; }
        private RenderTarget2D gPosition { get; }
        private RenderTarget2D gNormal { get; }
        private RenderTarget2D gAlbedo { get; }
        private RenderTarget2D gMetallicRoughness { get; }
        private RenderTarget2D deferredRenderTarget { get; }
        private RenderTargetBinding[] GBuffer { get; }
        private DeferredPBREffect DeferredPBREffect { get; }
        private SpriteBatch SpriteBatch { get; }
-        public Renderer(GraphicsDevice graphicsDevice, int renderDimensionsX, int renderDimensionsY)
+        public Renderer(
-        {
+            GraphicsDevice graphicsDevice,
            int renderDimensionsX,
            int renderDimensionsY,
            int numShadowCascades,
            int shadowMapSize
        ) {
            GraphicsDevice = graphicsDevice;
            RenderDimensionsX = renderDimensionsX;
            RenderDimensionsY = renderDimensionsY;
-            DepthRenderTarget = new RenderTarget2D(
+            ShadowMapSize = shadowMapSize;
-                GraphicsDevice,
+
            NumShadowCascades = (int)MathHelper.Clamp(numShadowCascades, 1, MAX_SHADOW_CASCADES);
            ShadowRenderTargets = new RenderTarget2D[numShadowCascades];
            for (var i = 0; i < numShadowCascades; i++)
            {
                ShadowRenderTargets[i] = new RenderTarget2D(
                    GraphicsDevice,
                    ShadowMapSize,
                    ShadowMapSize,
                    false,
                    SurfaceFormat.Single,
                    DepthFormat.Depth24
                );
            }
            ColorRenderTarget = new RenderTarget2D(
                graphicsDevice,
                renderDimensionsX,
                renderDimensionsY,
                false,
-                SurfaceFormat.HalfSingle, // unused
+                SurfaceFormat.Color,
-                DepthFormat.Depth24
+                DepthFormat.None,
                0,
                RenderTargetUsage.PreserveContents
            );
            DirectionalRenderTarget = new RenderTarget2D(
                graphicsDevice,
                renderDimensionsX,
                renderDimensionsY,
                false,
                SurfaceFormat.Color,
                DepthFormat.None,
                0,
                RenderTargetUsage.PreserveContents
            );
            gPosition = new RenderTarget2D(
@ -82,29 +128,33 @@ namespace Kav
                new RenderTargetBinding(gAlbedo),
                new RenderTargetBinding(gMetallicRoughness)
            };
            deferredRenderTarget = new RenderTarget2D(
                GraphicsDevice,
                renderDimensionsX,
                renderDimensionsY
            );
            SimpleDepthEffect = new SimpleDepthEffect(GraphicsDevice);
            DeferredPBREffect = new DeferredPBREffect(GraphicsDevice);
            DeferredAmbientLightEffect = new DeferredPBR_AmbientLightEffect(GraphicsDevice);
            DeferredPointLightEffect = new DeferredPBR_PointLightEffect(GraphicsDevice);
            DeferredDirectionalLightEffect = new DeferredPBR_DirectionalLightEffect(GraphicsDevice);
            DeferredDirectionalLightEffect.ShadowMapSize = ShadowMapSize;
            ToneMapEffect = new Effect(graphicsDevice, Resources.ToneMapEffect);
-            SpriteBatch = new SpriteBatch(GraphicsDevice);
+            FullscreenTriangle = new VertexBuffer(GraphicsDevice, typeof(VertexPositionTexture), 3, BufferUsage.WriteOnly);
            FullscreenTriangle.SetData(new VertexPositionTexture[3] {
                new VertexPositionTexture(new Vector3(-1, -3, 0), new Vector2(0, 2)),
                new VertexPositionTexture(new Vector3(-1, 1, 0), new Vector2(0, 0)),
                new VertexPositionTexture(new Vector3(3, 1, 0), new Vector2(2, 0))
            });
-            GraphicsDevice.SetRenderTarget(deferredRenderTarget);
+            SpriteBatch = new SpriteBatch(graphicsDevice);
            graphicsDevice.Clear(Color.White);
            GraphicsDevice.SetRenderTarget(null);
        }
        public void DeferredRender(
-            Camera camera,
+            PerspectiveCamera camera,
            IEnumerable<(Model, Matrix)> modelTransforms,
            IEnumerable<PointLight> pointLights,
-            IEnumerable<DirectionalLight> directionalLights
+            DirectionalLight directionalLight
        ) {
            // g-buffer pass
            GraphicsDevice.SetRenderTargets(GBuffer);
            GraphicsDevice.Clear(ClearOptions.Target | ClearOptions.DepthBuffer, Color.Black, 1f, 0);
            GraphicsDevice.DepthStencilState = DepthStencilState.Default;
@ -143,53 +193,186 @@ namespace Kav
                }
            }
-            GraphicsDevice.SetRenderTarget(null);
+            GraphicsDevice.SetRenderTarget(ColorRenderTarget);
-            GraphicsDevice.Clear(Color.CornflowerBlue);
+            GraphicsDevice.Clear(Color.Black);
            GraphicsDevice.BlendState = BlendState.Additive;
            GraphicsDevice.DepthStencilState = DepthStencilState.None;
-            DeferredPBREffect.GPosition = gPosition;
+            DeferredAmbientLightEffect.GPosition = gPosition;
-            DeferredPBREffect.GAlbedo = gAlbedo;
+            DeferredAmbientLightEffect.GAlbedo = gAlbedo;
-            DeferredPBREffect.GNormal = gNormal;
+
-            DeferredPBREffect.GMetallicRoughness = gMetallicRoughness;
+            foreach (var pass in DeferredAmbientLightEffect.CurrentTechnique.Passes)
-            DeferredPBREffect.EyePosition = Matrix.Invert(camera.View).Translation;
+            {
                pass.Apply();
                GraphicsDevice.SetVertexBuffer(FullscreenTriangle);
                GraphicsDevice.DrawPrimitives(PrimitiveType.TriangleList, 0, 1);
            }
            DeferredPointLightEffect.EyePosition = camera.Position;
            int i = 0;
            foreach (var pointLight in pointLights)
            {
-                if (i > DeferredPBREffect.MaxPointLights) { break; }
+                PointLightRender(pointLight);
                DeferredPBREffect.PointLights[i] = pointLight;
                i++;
            }
-            i = 0;
+            DirectionalLightRender(camera, modelTransforms, directionalLight);
-            foreach (var directionalLight in directionalLights)
+            // return;
-            {
+            // GraphicsDevice.SetRenderTarget(null);
-                if (i > DeferredPBREffect.MaxDirectionalLights) { break; }
+            // SpriteBatch.Begin(SpriteSortMode.Deferred, BlendState.NonPremultiplied);
-                DeferredPBREffect.DirectionalLights[i] = directionalLight;
+            // SpriteBatch.Draw(DirectionalRenderTarget, Vector2.Zero, Color.White);
-                i++;
+            // SpriteBatch.End();
            }
-            SpriteBatch.Begin(SpriteSortMode.Deferred, BlendState.NonPremultiplied, null, null, null, DeferredPBREffect);
+            GraphicsDevice.SetRenderTarget(null);
-            SpriteBatch.Draw(deferredRenderTarget, Vector2.Zero, Color.White);
+            GraphicsDevice.Clear(Color.Black);
            SpriteBatch.Begin(SpriteSortMode.Deferred, BlendState.Opaque, null, null, null, ToneMapEffect);
            SpriteBatch.Draw(ColorRenderTarget, Vector2.Zero, Color.White);
            SpriteBatch.End();
        }
-        public void Render(
+        private void PointLightRender(PointLight pointLight) 
-            Camera camera, 
+        {
-            IEnumerable<(Model, Matrix)> modelTransforms, 
+            DeferredPointLightEffect.GPosition = gPosition;
-            IEnumerable<PointLight> pointLights,
+            DeferredPointLightEffect.GAlbedo = gAlbedo;
-            IEnumerable<DirectionalLight> directionalLights
+            DeferredPointLightEffect.GNormal = gNormal;
-        ) {
+            DeferredPointLightEffect.GMetallicRoughness = gMetallicRoughness;    
-            Render(camera.View, camera.Projection, modelTransforms, pointLights, directionalLights);
+
            DeferredPointLightEffect.PointLightPosition = pointLight.Position;
            DeferredPointLightEffect.PointLightColor = 
                pointLight.Color.ToVector3() * pointLight.Intensity;
            foreach (var pass in DeferredPointLightEffect.CurrentTechnique.Passes)
            {
                pass.Apply();
                GraphicsDevice.SetVertexBuffer(FullscreenTriangle);
                GraphicsDevice.DrawPrimitives(PrimitiveType.TriangleList, 0, 1);
            }
        }
-        // for shadow mapping
+        private void DirectionalLightRender(
-        public void DepthRender(IEnumerable<(Model, Matrix)> modelTransforms, DirectionalLight directionalLight)
+            PerspectiveCamera camera,
-        {
+            IEnumerable<(Model, Matrix)> modelTransforms,
-            GraphicsDevice.SetRenderTarget(DepthRenderTarget);
+            DirectionalLight directionalLight
-            GraphicsDevice.Clear(ClearOptions.DepthBuffer, Color.Black, 1, 0);
+        ) {
            // render the individual shadow cascades
            var previousFarPlane = camera.NearPlane;
            for (var i = 0; i < NumShadowCascades; i++)
            {
                var farPlane = camera.FarPlane / (MathHelper.Max((NumShadowCascades - i - 1) * 2f, 1f));
-            SimpleDepthEffect.View = directionalLight.View;
+                // divide the view frustum 
-            SimpleDepthEffect.Projection = directionalLight.Projection;
+                var shadowCamera = new PerspectiveCamera(
                    camera.Position,
                    camera.Forward,
                    camera.Up,
                    camera.FieldOfView,
                    camera.AspectRatio,
                    previousFarPlane,
                    farPlane
                );
                // TODO: This is tightly coupled to the effect and it sucks
                RenderShadowMap(shadowCamera, modelTransforms, directionalLight, i);
                previousFarPlane = farPlane;
            }
            DeferredDirectionalLightEffect.GPosition = gPosition;
            DeferredDirectionalLightEffect.GAlbedo = gAlbedo;
            DeferredDirectionalLightEffect.GNormal = gNormal;
            DeferredDirectionalLightEffect.GMetallicRoughness = gMetallicRoughness;
            DeferredDirectionalLightEffect.ShadowMapOne = ShadowRenderTargets[0];
            if (NumShadowCascades > 1)
            {
                DeferredDirectionalLightEffect.ShadowMapTwo = ShadowRenderTargets[1];
            }
            if (NumShadowCascades > 2)
            {
                DeferredDirectionalLightEffect.ShadowMapThree = ShadowRenderTargets[2];
            }
            if (NumShadowCascades > 3)
            {
                DeferredDirectionalLightEffect.ShadowMapFour = ShadowRenderTargets[3];
            }
            DeferredDirectionalLightEffect.DirectionalLightDirection = directionalLight.Direction;
            DeferredDirectionalLightEffect.DirectionalLightColor = 
                directionalLight.Color.ToVector3() * directionalLight.Intensity;
            DeferredDirectionalLightEffect.ViewMatrix = camera.View;
            DeferredDirectionalLightEffect.EyePosition = Matrix.Invert(camera.View).Translation;
            GraphicsDevice.SetRenderTarget(ColorRenderTarget);
            GraphicsDevice.BlendState = BlendState.Additive;
            foreach (EffectPass pass in DeferredDirectionalLightEffect.CurrentTechnique.Passes)
            {
                pass.Apply();
                GraphicsDevice.SetVertexBuffer(FullscreenTriangle);
                GraphicsDevice.DrawPrimitives(PrimitiveType.TriangleList, 0, 1);
            }
        }
        private void RenderShadowMap(
            PerspectiveCamera camera, 
            IEnumerable<(Model, Matrix)> modelTransforms, 
            DirectionalLight directionalLight,
            int shadowCascadeIndex
        ) {
            GraphicsDevice.SetRenderTarget(ShadowRenderTargets[shadowCascadeIndex]);
            GraphicsDevice.Clear(Color.White);
            GraphicsDevice.DepthStencilState = DepthStencilState.Default;
            GraphicsDevice.BlendState = BlendState.Opaque;
            var cameraBoundingFrustum = new BoundingFrustum(camera.View * camera.Projection);
            Vector3[] frustumCorners = cameraBoundingFrustum.GetCorners();
            Vector3 frustumCenter = Vector3.Zero;
            for (var i = 0; i < frustumCorners.Length; i++)
            {
                frustumCenter += frustumCorners[i];
            }
            frustumCenter /= 8f;
            var lightView = Matrix.CreateLookAt(frustumCenter + directionalLight.Direction, frustumCenter, Vector3.Backward);
            for (var i = 0; i < frustumCorners.Length; i++)
            {
                frustumCorners[i] = Vector3.Transform(frustumCorners[i], lightView);
            }
            BoundingBox lightBox = BoundingBox.CreateFromPoints(frustumCorners);
            SimpleDepthEffect.View = lightView;
            SimpleDepthEffect.Projection = Matrix.CreateOrthographicOffCenter(
                lightBox.Min.X,
                lightBox.Max.X,
                lightBox.Min.Y,
                lightBox.Max.Y,
                -lightBox.Max.Z - 10f, // TODO: near clip plane needs scene AABB info to get rid of this magic value
                -lightBox.Min.Z
            );
            var lightSpaceMatrix = SimpleDepthEffect.View * SimpleDepthEffect.Projection;
            if (shadowCascadeIndex == 0)
            {
                DeferredDirectionalLightEffect.LightSpaceMatrixOne = lightSpaceMatrix;
            }
            else if (shadowCascadeIndex == 1)
            {
                DeferredDirectionalLightEffect.LightSpaceMatrixTwo = lightSpaceMatrix;
            }
            else if (shadowCascadeIndex == 2)
            {
                DeferredDirectionalLightEffect.LightSpaceMatrixThree = lightSpaceMatrix;
            }
            else if (shadowCascadeIndex == 3)
            {
                DeferredDirectionalLightEffect.LightSpaceMatrixFour = lightSpaceMatrix;
            }
            DeferredDirectionalLightEffect.CascadeFarPlanes[shadowCascadeIndex] = camera.FarPlane;
            foreach (var (model, transform) in modelTransforms)
            {
@ -220,6 +403,15 @@ namespace Kav
            }
        }
        public void Render(
            PerspectiveCamera camera, 
            IEnumerable<(Model, Matrix)> modelTransforms, 
            IEnumerable<PointLight> pointLights,
            IEnumerable<DirectionalLight> directionalLights
        ) {
            Render(camera.View, camera.Projection, modelTransforms, pointLights, directionalLights);
        }
        private void Render(
            Matrix view,
            Matrix projection,
@ -254,17 +446,6 @@ namespace Kav
                            }
                        }
                        if (meshPart.Effect is DirectionalLightEffect directionalLightEffect)
                        {
                            int i = 0;
                            foreach (var directionalLight in directionalLights)
                            {
                                if (i > directionalLightEffect.MaxDirectionalLights) { break; }
                                directionalLightEffect.DirectionalLights[i] = directionalLight;
                                i++;
                            }
                        }
                        foreach (var pass in meshPart.Effect.CurrentTechnique.Passes)
                        {
                            pass.Apply();
--- a/Resources.cs
+++ b/Resources.cs
@ -4,6 +4,41 @@ namespace Kav
 {
    internal class Resources
    {
        public static byte[] DeferredPBR_AmbientLightEffect
        {
            get
            {
                if (ambientLightEffect == null)
                {
                    ambientLightEffect = GetResource("DeferredPBR_AmbientLightEffect");
                }
                return ambientLightEffect;
            }
        }
        public static byte[] DeferredPBR_PointLightEffect
        {
            get
            {
                if (pointLightEffect == null)
                {
                    pointLightEffect = GetResource("DeferredPBR_PointLightEffect");
                }
                return pointLightEffect;
            }
        }
        public static byte[] DeferredPBR_DirectionalLightEffect
        {
            get
            {
                if (directionalLightEffect == null)
                {
                    directionalLightEffect = GetResource("DeferredPBR_DirectionalLightEffect");
                }
                return directionalLightEffect;
            }
        }
        public static byte[] DeferredPBR_GBufferEffect
        {
            get
@ -16,6 +51,18 @@ namespace Kav
            }
        }
        public static byte[] ToneMapEffect
        {
            get
            {
                if (toneMapEffect == null)
                {
                    toneMapEffect = GetResource("ToneMapEffect");
                }
                return toneMapEffect;
            }
        }
        public static byte[] DeferredPBREffect
        {
            get
@ -52,7 +99,11 @@ namespace Kav
            }
        }
        private static byte[] ambientLightEffect;
        private static byte[] pointLightEffect;
        private static byte[] directionalLightEffect;
        private static byte[] gBufferEffect;
        private static byte[] toneMapEffect;
        private static byte[] deferredPBREffect;
        private static byte[] pbrEffect;
        private static byte[] simpleDepthEffect;