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GiantsTools/Shaders/fx/Object.fx
2020-11-30 17:40:33 -08:00

306 lines
8.2 KiB
HLSL

#include "../fxh/Constants.fxh"
#include "../fxh/Lighting.fxh"
#include "../fxh/Transform.fxh"
#include "../fxh/Fog.fxh"
shared texture g_Texture0;
shared texture g_Texture1;
shared DirectionalLightInfo g_DirectionalLights;
shared Material g_Material;
shared WorldTransforms g_WorldTransforms;
shared float4x4 g_EnvironmentTextureTransform;
shared float4 g_TextureFactor;
shared BlendStageInfo g_BlendStages;
shared ViewTransforms g_ViewTransforms;
shared ColorMixMode g_ColorMixMode;
sampler g_ObjTextureSampler : register(s0) =
sampler_state
{
Texture = <g_Texture0>;
MipFilter = LINEAR;
MinFilter = LINEAR;
MagFilter = LINEAR;
};
sampler g_EnvTextureSampler =
sampler_state
{
Texture = <g_Texture1>;
MipFilter = LINEAR;
MinFilter = LINEAR;
MagFilter = LINEAR;
};
shared FogParams g_Fog;
// =======================================================
// Pixel and vertex lighting techniques
//
Lighting DoDirectionalLight(float3 worldPos, float3 N, int i)
{
Lighting Out;
Out.Diffuse = CalculateDirectionalDiffuse(
N,
-g_DirectionalLights.Direction[i],
g_DirectionalLights.Diffuse[i]);
Out.Specular = CalculateDirectionalSpecular(
worldPos,
g_ViewTransforms.CameraPosition.xyz,
N,
-g_DirectionalLights.Direction[i],
g_DirectionalLights.Specular[i],
g_Material.Power);
return Out;
}
Lighting ComputeLighting(float3 worldPos, float3 N)
{
Lighting finalLighting = (Lighting)0;
for (int i = 0; i < g_DirectionalLights.Count; i++)
{
Lighting lighting = DoDirectionalLight(worldPos, N, i);
finalLighting.Diffuse += lighting.Diffuse;
finalLighting.Specular += lighting.Specular;
}
float4 ambient = g_Material.Ambient * g_DirectionalLights.Ambient;
float4 diffuse = g_Material.Diffuse * finalLighting.Diffuse;
float4 specular = g_Material.Specular * finalLighting.Specular;
finalLighting.Diffuse = saturate(ambient + diffuse + g_Material.Emissive);
finalLighting.Specular = saturate(specular);
return finalLighting;
}
struct PixelLightingVSOutput
{
float4 Pos : POSITION;
float2 Tex0 : TEXCOORD0;
float3 Normal : TEXCOORD1;
float3 WorldPos : TEXCOORD2;
float3 EnvMapTex : TEXCOORD3;
float4 BumpColor : TEXCOORD4;
float Fog : FOG;
};
float4 GetColorArg(int colorArg, float4 textureColor, float4 diffuseColor)
{
float4 result;
if (colorArg == D3DTA_TEXTURE) result = textureColor;
else if (colorArg == D3DTA_DIFFUSE) result = diffuseColor;
else if (colorArg == D3DTA_TFACTOR) result = g_TextureFactor;
else result = float4(1.f, 1.f, 1.f, 1.f);
return result;
}
float4 Modulate(int stageIndex, float4 textureColor, float4 diffuseColor, float factor)
{
float4 left = GetColorArg(g_BlendStages.BlendStages[stageIndex].colorArg1, textureColor, diffuseColor);
float4 right = GetColorArg(g_BlendStages.BlendStages[stageIndex].colorArg2, textureColor, diffuseColor);
return (left * right) * factor;
}
float4 ProcessStages(float4 textureColor, float4 diffuseColor)
{
float4 output = 0;
for (int i = 0; i < g_BlendStages.Count; i++)
{
if (g_BlendStages.BlendStages[i].colorOp == D3DTOP_MODULATE4X || g_BlendStages.BlendStages[i].colorOp == D3DTOP_MODULATE)
{
float modulateFactor =
(4.0f * (g_BlendStages.BlendStages[i].colorOp == D3DTOP_MODULATE4X)) +
(1.0f * (g_BlendStages.BlendStages[i].colorOp == D3DTOP_MODULATE));
output += Modulate(i, textureColor, diffuseColor, modulateFactor);
}
else if (g_BlendStages.BlendStages[i].colorOp == D3DTOP_DOTPRODUCT3)
{
output = float4(1, 0, 0, 1);
}
}
return output;
}
struct PixelLightingPSOutput
{
float4 Diffuse : COLOR0;
};
PixelLightingVSOutput PixelLightingVS(
float4 vPosition : POSITION0,
float3 vNormal : NORMAL0,
float4 color : COLOR0,
float2 tc : TEXCOORD0)
{
// Simple transform, pre-compute as much as we can for the pixel shader
PixelLightingVSOutput output = (PixelLightingVSOutput)0;
vNormal = normalize(vNormal);
output.Pos = mul(vPosition, g_WorldTransforms.WorldViewProjection);
output.Normal = mul(vNormal, (float3x3)g_WorldTransforms.World);
output.WorldPos = mul(vPosition, g_WorldTransforms.World);
output.Tex0 = tc;
output.BumpColor = color;
float3 P = mul(vPosition, g_WorldTransforms.WorldView);
float d = length(P);
output.Fog = CalculateFogFactor(g_Fog.FogMax, g_Fog.FogMin, d);
if (g_ColorMixMode.EnvironmentMappingEnabled)
{
// Generate cube texture coordinates
// DX9 FFP formula: R = 2(E dot N) * N - E
float3 E = normalize(g_ViewTransforms.CameraPosition.xyz - output.WorldPos);
float3 N = mul(vNormal, (float3x3)g_WorldTransforms.WorldView);
float4 R = float4((2.f * dot(E, N) * N - E), 0);
output.EnvMapTex = mul(g_EnvironmentTextureTransform, R);
}
return output;
}
float4 PixelLightingPS(PixelLightingVSOutput input) : COLOR0
{
float4 color = tex2D(g_ObjTextureSampler, input.Tex0);
Lighting lighting = ComputeLighting(input.WorldPos, input.Normal);
// Emulate FFP texture stages
float4 finalColor = ProcessStages(color, lighting.Diffuse) + lighting.Specular;
// Apply cubic environment mapping if enabled
if (g_ColorMixMode.EnvironmentMappingEnabled)
{
float4 envMapColor = texCUBE(g_EnvTextureSampler, input.EnvMapTex);
if (g_BlendStages.BlendStages[1].colorOp == D3DTOP_BLENDFACTORALPHA)
finalColor = (finalColor * g_TextureFactor.a) + (envMapColor * (1 - g_TextureFactor.a));
else if (g_BlendStages.BlendStages[1].colorOp == D3DTOP_BLENDCURRENTALPHA)
finalColor = float4(1, 0, 0, 0);
}
// Apply linear pixel fog
if (g_Fog.Enabled)
{
finalColor = ApplyPixelFog(finalColor, input.Fog, g_Fog.Color);
}
/*
if (input.BumpColor.r != 0)
{
finalColor = float4(1, 1, 1, 1);
}
*/
return finalColor;
}
technique PixelLighting
{
pass P0
{
PixelShader = compile ps_3_0 PixelLightingPS();
VertexShader = compile vs_3_0 PixelLightingVS();
}
}
struct VertexLightingVSOutput
{
float4 Pos : POSITION;
float4 Diffuse : COLOR0;
float4 Specular : COLOR1;
float2 Tex0 : TEXCOORD0;
float4 BumpColor : TEXCOORD1;
float Fog : FOG;
};
VertexLightingVSOutput VertexLightingVS(
float4 vPosition : POSITION0,
float3 vNormal : NORMAL0,
float4 color : COLOR0,
float2 tc : TEXCOORD0,
float fog : FOG)
{
VertexLightingVSOutput output;
output.Pos = mul(vPosition, g_WorldTransforms.WorldViewProjection);
float4 worldPos = mul(vPosition, g_WorldTransforms.World);
float3 normal = mul(normalize(vNormal), (float3x3)g_WorldTransforms.World);
Lighting lighting = ComputeLighting(worldPos, normal);
output.Diffuse = lighting.Diffuse;
output.Specular = lighting.Specular;
output.BumpColor = color;
output.Fog = fog;
output.Tex0 = tc;
return output;
}
technique VertexLighting
{
pass P0
{
VertexShader = compile vs_2_0 VertexLightingVS();
}
}
// =======================================================
// Color per vertex
//
struct ColorPerVertexVSOutput
{
float4 Pos : POSITION;
float2 Tex0 : TEXCOORD0;
float4 Color : COLOR0;
float Fog : FOG;
};
float4 ColorPerVertexPS(ColorPerVertexVSOutput input) : COLOR0
{
float4 color = tex2D(g_ObjTextureSampler, input.Tex0); //* input.Color;
return color;
}
ColorPerVertexVSOutput ColorPerVertexVS(
float4 vPosition : POSITION0,
float2 tc : TEXCOORD0,
float4 color : COLOR0,
float fog : FOG)
{
// Simple transform, pre-compute as much as we can for the pixel shader
ColorPerVertexVSOutput output = (ColorPerVertexVSOutput)0;
output.Pos = mul(vPosition, g_WorldTransforms.WorldViewProjection);
output.Tex0 = tc;
output.Color = color;
float3 P = mul(vPosition, g_WorldTransforms.WorldView); //position in view space
float d = length(P);
output.Fog = fog;
return output;
}
technique ColorPerVertex
{
pass P0
{
//PixelShader = compile ps_3_0 ColorPerVertexPS();
VertexShader = compile vs_2_0 ColorPerVertexVS();
}
}