mirror of
https://github.com/PixarAnimationStudios/OpenSubdiv
synced 2024-12-05 17:21:04 +00:00
7c73cf0128
- changed ptex layout data types in shaders to match srv format - changed ptex srv type to unorm format for uchar data - fixed hlsl compiler warning: initialized edgeDistance of OutputVertex struct in domain shader even if we are not in wireframe mode - added directx debug device and enabled automatic break points to easily spot dx errors
475 lines
15 KiB
HLSL
475 lines
15 KiB
HLSL
//
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// Copyright 2013 Pixar
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//
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// Licensed under the Apache License, Version 2.0 (the "Apache License")
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// with the following modification; you may not use this file except in
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// compliance with the Apache License and the following modification to it:
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// Section 6. Trademarks. is deleted and replaced with:
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//
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// 6. Trademarks. This License does not grant permission to use the trade
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// names, trademarks, service marks, or product names of the Licensor
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// and its affiliates, except as required to comply with Section 4(c) of
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// the License and to reproduce the content of the NOTICE file.
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//
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// You may obtain a copy of the Apache License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the Apache License with the above modification is
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// distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
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// KIND, either express or implied. See the Apache License for the specific
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// language governing permissions and limitations under the Apache License.
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//
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struct OutputPointVertex {
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float4 positionOut : SV_Position;
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};
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cbuffer Transform : register( b0 ) {
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float4x4 ModelViewMatrix;
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float4x4 ProjectionMatrix;
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float4x4 ModelViewProjectionMatrix;
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};
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cbuffer Tessellation : register( b1 ) {
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float TessLevel;
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int GregoryQuadOffsetBase;
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int PrimitiveIdBase;
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};
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cbuffer Config : register( b3 ) {
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float displacementScale;
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float mipmapBias;
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};
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float4x4 OsdModelViewMatrix()
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{
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return ModelViewMatrix;
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}
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float4x4 OsdProjectionMatrix()
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{
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return ProjectionMatrix;
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}
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float4x4 OsdModelViewProjectionMatrix()
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{
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return ModelViewProjectionMatrix;
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}
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float OsdTessLevel()
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{
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return TessLevel;
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}
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int OsdGregoryQuadOffsetBase()
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{
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return GregoryQuadOffsetBase;
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}
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int OsdPrimitiveIdBase()
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{
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return PrimitiveIdBase;
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}
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// ---------------------------------------------------------------------------
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#if defined(DISPLACEMENT_HW_BILINEAR) \
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|| defined(DISPLACEMENT_BILINEAR) \
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|| defined(DISPLACEMENT_BIQUADRATIC) \
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|| defined(NORMAL_HW_SCREENSPACE) \
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|| defined(NORMAL_SCREENSPACE) \
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|| defined(NORMAL_BIQUADRATIC) \
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|| defined(NORMAL_BIQUADRATIC_WG)
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Texture2DArray textureDisplace_Data : register(t6);
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Buffer<uint> textureDisplace_Packing : register(t7);
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#endif
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#if defined(DISPLACEMENT_HW_BILINEAR) \
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|| defined(DISPLACEMENT_BILINEAR) \
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|| defined(DISPLACEMENT_BIQUADRATIC)
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#undef OSD_DISPLACEMENT_CALLBACK
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#define OSD_DISPLACEMENT_CALLBACK \
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output.position = \
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displacement(output.position, \
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output.normal, \
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output.patchCoord);
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float4 displacement(float4 position, float3 normal, float4 patchCoord)
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{
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#if defined(DISPLACEMENT_HW_BILINEAR)
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float disp = PtexLookupFast(patchCoord,
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textureDisplace_Data,
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textureDisplace_Packing).x;
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#elif defined(DISPLACEMENT_BILINEAR)
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float disp = PtexMipmapLookup(patchCoord, mipmapBias,
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textureDisplace_Data,
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textureDisplace_Packing).x;
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#elif defined(DISPLACEMENT_BIQUADRATIC)
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float disp = PtexMipmapLookupQuadratic(patchCoord, mipmapBias,
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textureDisplace_Data,
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textureDisplace_Packing).x;
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#else
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float disp(0);
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#endif
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return position + float4(disp*normal, 0) * displacementScale;
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}
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#endif
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#line 20117
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float4 GeneratePatchCoord(float2 localUV, int primitiveID) // for non-adpative
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{
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int2 ptexIndex = OsdPatchParamBuffer[GetPrimitiveID(primitiveID)].xy;
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int faceID = ptexIndex.x;
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int lv = 1 << ((ptexIndex.y & 0xf) - ((ptexIndex.y >> 4) & 1));
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int u = (ptexIndex.y >> 17) & 0x3ff;
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int v = (ptexIndex.y >> 7) & 0x3ff;
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float2 uv = localUV;
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uv = (uv * float2(1, 1)/lv) + float2(u, v)/lv;
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return float4(uv.x, uv.y, lv+0.5, faceID+0.5);
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}
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// ---------------------------------------------------------------------------
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// Vertex Shader
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// ---------------------------------------------------------------------------
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void vs_main( in InputVertex input,
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out OutputVertex output )
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{
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output.positionOut = mul(ModelViewProjectionMatrix, input.position);
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output.position = mul(ModelViewMatrix, input.position);
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output.normal = mul(ModelViewMatrix,float4(input.normal, 0)).xyz;
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}
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// ---------------------------------------------------------------------------
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// Geometry Shader
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// ---------------------------------------------------------------------------
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OutputVertex
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outputVertex(OutputVertex input, float3 normal)
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{
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OutputVertex v = input;
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v.normal = normal;
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return v;
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}
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OutputVertex
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outputVertex(OutputVertex input, float3 normal, float4 patchCoord)
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{
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OutputVertex v = input;
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v.normal = normal;
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v.patchCoord = patchCoord;
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return v;
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}
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#if defined(GEOMETRY_OUT_WIRE) || defined(GEOMETRY_OUT_LINE)
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#ifdef PRIM_TRI
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#define EDGE_VERTS 3
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#endif
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#ifdef PRIM_QUAD
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#define EDGE_VERTS 4
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#endif
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static float VIEWPORT_SCALE = 1024.0; // XXXdyu
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float edgeDistance(float2 p, float2 p0, float2 p1)
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{
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return VIEWPORT_SCALE *
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abs((p.x - p0.x) * (p1.y - p0.y) -
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(p.y - p0.y) * (p1.x - p0.x)) / length(p1.xy - p0.xy);
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}
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OutputVertex
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outputWireVertex(OutputVertex input, float3 normal,
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int index, float2 edgeVerts[EDGE_VERTS])
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{
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OutputVertex v = input;
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v.normal = normal;
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v.edgeDistance[0] =
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edgeDistance(edgeVerts[index], edgeVerts[0], edgeVerts[1]);
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v.edgeDistance[1] =
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edgeDistance(edgeVerts[index], edgeVerts[1], edgeVerts[2]);
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#ifdef PRIM_TRI
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v.edgeDistance[2] =
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edgeDistance(edgeVerts[index], edgeVerts[2], edgeVerts[0]);
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#endif
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#ifdef PRIM_QUAD
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v.edgeDistance[2] =
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edgeDistance(edgeVerts[index], edgeVerts[2], edgeVerts[3]);
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v.edgeDistance[3] =
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edgeDistance(edgeVerts[index], edgeVerts[3], edgeVerts[0]);
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#endif
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return v;
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}
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#endif
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#ifdef PRIM_QUAD
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[maxvertexcount(6)]
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void gs_main( lineadj OutputVertex input[4],
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inout TriangleStream<OutputVertex> triStream,
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uint primitiveID : SV_PrimitiveID)
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{
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float3 A = (input[0].position - input[1].position).xyz;
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float3 B = (input[3].position - input[1].position).xyz;
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float3 C = (input[2].position - input[1].position).xyz;
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float3 n0 = normalize(cross(B, A));
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float4 patchCoord[4];
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patchCoord[0] = GeneratePatchCoord(float2(0, 0), primitiveID);
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patchCoord[1] = GeneratePatchCoord(float2(1, 0), primitiveID);
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patchCoord[2] = GeneratePatchCoord(float2(1, 1), primitiveID);
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patchCoord[3] = GeneratePatchCoord(float2(0, 1), primitiveID);
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triStream.Append(outputVertex(input[0], n0, patchCoord[0]));
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triStream.Append(outputVertex(input[1], n0, patchCoord[1]));
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triStream.Append(outputVertex(input[3], n0, patchCoord[3]));
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triStream.RestartStrip();
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triStream.Append(outputVertex(input[3], n0, patchCoord[3]));
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triStream.Append(outputVertex(input[1], n0, patchCoord[1]));
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triStream.Append(outputVertex(input[2], n0, patchCoord[2]));
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triStream.RestartStrip();
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}
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#else // PRIM_TRI
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[maxvertexcount(3)]
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void gs_main( triangle OutputVertex input[3],
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inout TriangleStream<OutputVertex> triStream )
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{
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float4 position[3];
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float4 patchCoord[3];
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float3 normal[3];
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// patch coords are computed in tessellation shader
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patchCoord[0] = input[0].patchCoord;
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patchCoord[1] = input[1].patchCoord;
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patchCoord[2] = input[2].patchCoord;
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position[0] = input[0].position;
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position[1] = input[1].position;
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position[2] = input[2].position;
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#ifdef NORMAL_FACET
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// emit flat normals for displaced surface
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float3 A = (position[0] - position[1]).xyz;
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float3 B = (position[2] - position[1]).xyz;
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normal[0]= normalize(cross(B, A));
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normal[1] = normal[0];
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normal[2] = normal[0];
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#else
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normal[0] = input[0].normal;
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normal[1] = input[1].normal;
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normal[2] = input[2].normal;
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#endif
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#if defined(GEOMETRY_OUT_WIRE) || defined(GEOMETRY_OUT_LINE)
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float2 edgeVerts[3];
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edgeVerts[0] = input[0].positionOut.xy / input[0].positionOut.w;
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edgeVerts[1] = input[1].positionOut.xy / input[1].positionOut.w;
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edgeVerts[2] = input[2].positionOut.xy / input[2].positionOut.w;
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triStream.Append(outputWireVertex(input[0], normal[0], 0, edgeVerts));
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triStream.Append(outputWireVertex(input[1], normal[1], 1, edgeVerts));
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triStream.Append(outputWireVertex(input[2], normal[2], 2, edgeVerts));
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#else
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triStream.Append(outputVertex(input[0], normal[0]));
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triStream.Append(outputVertex(input[1], normal[1]));
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triStream.Append(outputVertex(input[2], normal[2]));
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#endif
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}
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#endif
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// ---------------------------------------------------------------------------
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// Lighting
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// ---------------------------------------------------------------------------
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#define NUM_LIGHTS 2
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struct LightSource {
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float4 position;
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float4 ambient;
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float4 diffuse;
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float4 specular;
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};
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cbuffer Lighting : register( b2 ) {
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LightSource lightSource[NUM_LIGHTS];
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};
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float4
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lighting(float4 texColor, float3 Peye, float3 Neye, float occ)
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{
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float4 color = float4(0.0, 0.0, 0.0, 0.0);
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float3 n = Neye;
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for (int i = 0; i < NUM_LIGHTS; ++i) {
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float4 Plight = lightSource[i].position;
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float3 l = (Plight.w == 0.0)
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? normalize(Plight.xyz) : normalize(Plight.xyz - Peye);
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float3 h = normalize(l + float3(0,0,1)); // directional viewer
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float d = max(0.0, dot(n, l));
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float s = pow(max(0.0, dot(n, h)), 64.0f);
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color += (1.0 - occ) * ((lightSource[i].ambient +
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d * lightSource[i].diffuse) * texColor +
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s * lightSource[i].specular);
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}
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color.a = 1.0;
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return color;
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}
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// ---------------------------------------------------------------------------
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// Pixel Shader
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// ---------------------------------------------------------------------------
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float4
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edgeColor(float4 Cfill, float4 edgeDistance)
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{
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#if defined(GEOMETRY_OUT_WIRE) || defined(GEOMETRY_OUT_LINE)
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#ifdef PRIM_TRI
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float d =
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min(edgeDistance[0], min(edgeDistance[1], edgeDistance[2]));
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#endif
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#ifdef PRIM_QUAD
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float d =
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min(min(edgeDistance[0], edgeDistance[1]),
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min(edgeDistance[2], edgeDistance[3]));
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#endif
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float4 Cedge = float4(1.0, 1.0, 0.0, 1.0);
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float p = exp2(-2 * d * d);
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#if defined(GEOMETRY_OUT_WIRE)
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if (p < 0.25) discard;
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#endif
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Cfill.rgb = lerp(Cfill.rgb, Cedge.rgb, p);
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#endif
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return Cfill;
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}
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// ---------------------------------------------------------------------------
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// Pixel Shader
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// ---------------------------------------------------------------------------
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#if defined(COLOR_PTEX_NEAREST) || \
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defined(COLOR_PTEX_HW_BILINEAR) || \
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defined(COLOR_PTEX_BILINEAR) || \
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defined(COLOR_PTEX_BIQUADRATIC)
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Texture2DArray textureImage_Data : register(t4);
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Buffer<uint> textureImage_Packing : register(t5);
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#endif
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#ifdef USE_PTEX_OCCLUSION
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Texture2DArray textureOcclusion_Data : register(t8);
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Buffer<uint> textureOcclusion_Packing : register(t9);
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#endif
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#ifdef USE_PTEX_SPECULAR
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Texture2DArray textureSpecular_Data : register(t10);
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Buffer<uint> textureSpecular_Packing : register(t11);
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#endif
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void
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ps_main(in OutputVertex input,
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out float4 outColor : SV_Target )
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{
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// ------------ normal ---------------
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#if defined(NORMAL_HW_SCREENSPACE) || defined(NORMAL_SCREENSPACE)
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float3 normal = perturbNormalFromDisplacement(input.position.xyz,
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input.normal,
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input.patchCoord);
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#elif defined(NORMAL_BIQUADRATIC) || defined(NORMAL_BIQUADRATIC_WG)
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float4 du, dv;
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float4 disp = PtexMipmapLookupQuadratic(du, dv, input.patchCoord,
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mipmapBias,
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textureDisplace_Data,
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textureDisplace_Packing);
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disp *= displacementScale;
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du *= displacementScale;
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dv *= displacementScale;
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float3 n = normalize(cross(input.tangent, input.bitangent));
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float3 tangent = input.tangent + n * du.x;
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float3 bitangent = input.bitangent + n * dv.x;
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#if defined(NORMAL_BIQUADRATIC_WG)
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tangent += input.Nu * disp.x;
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bitangent += input.Nv * disp.x;
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#endif
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float3 normal = normalize(cross(tangent, bitangent));
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#else
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float3 normal = input.normal;
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#endif
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// ------------ color ---------------
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#if defined(COLOR_PTEX_NEAREST)
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float4 texColor = PtexLookupNearest(input.patchCoord,
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textureImage_Data,
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textureImage_Packing);
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#elif defined(COLOR_PTEX_HW_BILINEAR)
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float4 texColor = PtexLookupFast(input.patchCoord,
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textureImage_Data,
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textureImage_Packing);
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#elif defined(COLOR_PTEX_BILINEAR)
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float4 texColor = PtexMipmapLookup(input.patchCoord, mipmapBias,
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textureImage_Data,
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textureImage_Packing);
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#elif defined(COLOR_PTEX_BIQUADRATIC)
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float4 texColor = PtexMipmapLookupQuadratic(input.patchCoord, mipmapBias,
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textureImage_Data,
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textureImage_Packing);
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#elif defined(COLOR_PATCHTYPE)
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float4 texColor = edgeColor(lighting(overrideColor, input.position.xyz, normal, 0),
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input.edgeDistance);
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outColor = texColor;
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return;
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#elif defined(COLOR_PATCHCOORD)
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float4 texColor = edgeColor(lighting(input.patchCoord, input.position.xyz, normal, 0),
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input.edgeDistance);
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outColor = texColor;
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return;
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#elif defined(COLOR_NORMAL)
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float4 texColor = edgeColor(float4(normal.x, normal.y, normal.z, 1),
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input.edgeDistance);
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outColor = texColor;
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return;
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#else // COLOR_NONE
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float4 texColor = float4(0.5, 0.5, 0.5, 1);
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#endif
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// ------------ occlusion ---------------
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#ifdef USE_PTEX_OCCLUSION
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float occ = PtexLookup(input.patchCoord,
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textureOcclusion_Data,
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textureOcclusion_Packing).x;
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#else
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float occ = 0.0;
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#endif
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// ------------ specular ---------------
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#ifdef USE_PTEX_SPECULAR
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float specular = PtexLookup(input.patchCoord,
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textureSpecular_Data,
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textureSpecular_Packing).x;
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#else
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float specular = 1.0;
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#endif
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// ------------ lighting ---------------
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float4 Cf = lighting(texColor, input.position.xyz, normal, occ);
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// ------------ wireframe ---------------
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outColor = edgeColor(Cf, input.edgeDistance);
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}
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