Kav/Effects/HLSL/DeferredPBR_DirectionalLigh...

190 lines
4.6 KiB
HLSL

#include "Macros.fxh" //from FNA
#include "Lighting.fxh"
#include "Shadow.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
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
float ComputeShadow(float3 positionWorldSpace, float3 N, float3 L)
{
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;
}
// PCF + Poisson soft shadows
if (shadowCascadeIndex == 0)
{
return PoissonShadow(
positionWorldSpace,
N,
L,
lightSpaceMatrix,
SAMPLER(shadowMapOne),
ShadowMapSize
);
}
else if (shadowCascadeIndex == 1)
{
return PoissonShadow(
positionWorldSpace,
N,
L,
lightSpaceMatrix,
SAMPLER(shadowMapTwo),
ShadowMapSize
);
}
else if (shadowCascadeIndex == 2)
{
return PoissonShadow(
positionWorldSpace,
N,
L,
lightSpaceMatrix,
SAMPLER(shadowMapThree),
ShadowMapSize
);
}
else
{
return PoissonShadow(
positionWorldSpace,
N,
L,
lightSpaceMatrix,
SAMPLER(shadowMapFour),
ShadowMapSize
);
}
}
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();
}
}