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// Copyright 2016 The SwiftShader Authors. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "VertexPipeline.hpp"
#include "Renderer/Vertex.hpp"
#include "Renderer/Renderer.hpp"
#include "Common/Debug.hpp"
#include <string.h>
#include <stdlib.h>
#include <stdio.h>
#undef max
#undef min
namespace sw
{
extern bool secondaryColor;
VertexPipeline::VertexPipeline(const VertexProcessor::State &state) : VertexRoutine(state, 0)
{
}
VertexPipeline::~VertexPipeline()
{
}
Vector4f VertexPipeline::transformBlend(const Register &src, const Pointer<Byte> &matrix, bool homogeneous)
{
Vector4f dst;
if(state.vertexBlendMatrixCount == 0)
{
dst = transform(src, matrix, homogeneous);
}
else
{
UInt index0[4];
UInt index1[4];
UInt index2[4];
UInt index3[4];
if(state.indexedVertexBlendEnable)
{
for(int i = 0; i < 4; i++)
{
Float4 B = v[BlendIndices].x;
UInt indices;
switch(i)
{
case 0: indices = As<UInt>(Float(B.x)); break;
case 1: indices = As<UInt>(Float(B.y)); break;
case 2: indices = As<UInt>(Float(B.z)); break;
case 3: indices = As<UInt>(Float(B.w)); break;
}
index0[i] = (indices & 0x000000FF) << 6;
index1[i] = (indices & 0x0000FF00) >> 2;
index2[i] = (indices & 0x00FF0000) >> 10;
index3[i] = (indices & 0xFF000000) >> 18;
}
}
else
{
for(int i = 0; i < 4; i++)
{
index0[i] = 0 * 64;
index1[i] = 1 * 64;
index2[i] = 2 * 64;
index3[i] = 3 * 64;
}
}
Float4 weight0;
Float4 weight1;
Float4 weight2;
Float4 weight3;
switch(state.vertexBlendMatrixCount)
{
case 4: weight2 = v[BlendWeight].z;
case 3: weight1 = v[BlendWeight].y;
case 2: weight0 = v[BlendWeight].x;
case 1:
break;
}
if(state.vertexBlendMatrixCount == 1)
{
dst = transform(src, matrix, index0, homogeneous);
}
else if(state.vertexBlendMatrixCount == 2)
{
weight1 = Float4(1.0f) - weight0;
Vector4f pos0;
Vector4f pos1;
pos0 = transform(src, matrix, index0, homogeneous);
pos1 = transform(src, matrix, index1, homogeneous);
dst.x = pos0.x * weight0 + pos1.x * weight1; // FIXME: Vector4f operators
dst.y = pos0.y * weight0 + pos1.y * weight1;
dst.z = pos0.z * weight0 + pos1.z * weight1;
dst.w = pos0.w * weight0 + pos1.w * weight1;
}
else if(state.vertexBlendMatrixCount == 3)
{
weight2 = Float4(1.0f) - (weight0 + weight1);
Vector4f pos0;
Vector4f pos1;
Vector4f pos2;
pos0 = transform(src, matrix, index0, homogeneous);
pos1 = transform(src, matrix, index1, homogeneous);
pos2 = transform(src, matrix, index2, homogeneous);
dst.x = pos0.x * weight0 + pos1.x * weight1 + pos2.x * weight2;
dst.y = pos0.y * weight0 + pos1.y * weight1 + pos2.y * weight2;
dst.z = pos0.z * weight0 + pos1.z * weight1 + pos2.z * weight2;
dst.w = pos0.w * weight0 + pos1.w * weight1 + pos2.w * weight2;
}
else if(state.vertexBlendMatrixCount == 4)
{
weight3 = Float4(1.0f) - (weight0 + weight1 + weight2);
Vector4f pos0;
Vector4f pos1;
Vector4f pos2;
Vector4f pos3;
pos0 = transform(src, matrix, index0, homogeneous);
pos1 = transform(src, matrix, index1, homogeneous);
pos2 = transform(src, matrix, index2, homogeneous);
pos3 = transform(src, matrix, index3, homogeneous);
dst.x = pos0.x * weight0 + pos1.x * weight1 + pos2.x * weight2 + pos3.x * weight3;
dst.y = pos0.y * weight0 + pos1.y * weight1 + pos2.y * weight2 + pos3.y * weight3;
dst.z = pos0.z * weight0 + pos1.z * weight1 + pos2.z * weight2 + pos3.z * weight3;
dst.w = pos0.w * weight0 + pos1.w * weight1 + pos2.w * weight2 + pos3.w * weight3;
}
}
return dst;
}
void VertexPipeline::pipeline(UInt &index)
{
Vector4f position;
Vector4f normal;
if(!state.preTransformed)
{
position = transformBlend(v[Position], Pointer<Byte>(data + OFFSET(DrawData,ff.transformT)), true);
}
else
{
position = v[PositionT];
}
o[Pos].x = position.x;
o[Pos].y = position.y;
o[Pos].z = position.z;
o[Pos].w = position.w;
Vector4f vertexPosition = transformBlend(v[Position], Pointer<Byte>(data + OFFSET(DrawData,ff.cameraTransformT)), true);
if(state.vertexNormalActive)
{
normal = transformBlend(v[Normal], Pointer<Byte>(data + OFFSET(DrawData,ff.normalTransformT)), false);
if(state.normalizeNormals)
{
normal = normalize(normal);
}
}
if(!state.vertexLightingActive)
{
// FIXME: Don't process if not used at all
if(state.diffuseActive && state.input[Color0])
{
Vector4f diffuse = v[Color0];
o[C0].x = diffuse.x;
o[C0].y = diffuse.y;
o[C0].z = diffuse.z;
o[C0].w = diffuse.w;
}
else
{
o[C0].x = Float4(1.0f);
o[C0].y = Float4(1.0f);
o[C0].z = Float4(1.0f);
o[C0].w = Float4(1.0f);
}
// FIXME: Don't process if not used at all
if(state.specularActive && state.input[Color1])
{
Vector4f specular = v[Color1];
o[C1].x = specular.x;
o[C1].y = specular.y;
o[C1].z = specular.z;
o[C1].w = specular.w;
}
else
{
o[C1].x = Float4(0.0f);
o[C1].y = Float4(0.0f);
o[C1].z = Float4(0.0f);
o[C1].w = Float4(1.0f);
}
}
else
{
o[C0].x = Float4(0.0f);
o[C0].y = Float4(0.0f);
o[C0].z = Float4(0.0f);
o[C0].w = Float4(0.0f);
o[C1].x = Float4(0.0f);
o[C1].y = Float4(0.0f);
o[C1].z = Float4(0.0f);
o[C1].w = Float4(0.0f);
Vector4f ambient;
Float4 globalAmbient = *Pointer<Float4>(data + OFFSET(DrawData,ff.globalAmbient)); // FIXME: Unpack
ambient.x = globalAmbient.x;
ambient.y = globalAmbient.y;
ambient.z = globalAmbient.z;
for(int i = 0; i < 8; i++)
{
if(!(state.vertexLightActive & (1 << i)))
{
continue;
}
Vector4f L; // Light vector
Float4 att; // Attenuation
// Attenuation
{
Float4 d; // Distance
L.x = L.y = L.z = *Pointer<Float4>(data + OFFSET(DrawData,ff.lightPosition[i])); // FIXME: Unpack
L.x = L.x.xxxx;
L.y = L.y.yyyy;
L.z = L.z.zzzz;
L.x -= vertexPosition.x;
L.y -= vertexPosition.y;
L.z -= vertexPosition.z;
d = dot3(L, L);
d = RcpSqrt_pp(d); // FIXME: Sufficient precision?
L.x *= d;
L.y *= d;
L.z *= d;
d = Rcp_pp(d); // FIXME: Sufficient precision?
Float4 q = *Pointer<Float4>(data + OFFSET(DrawData,ff.attenuationQuadratic[i]));
Float4 l = *Pointer<Float4>(data + OFFSET(DrawData,ff.attenuationLinear[i]));
Float4 c = *Pointer<Float4>(data + OFFSET(DrawData,ff.attenuationConstant[i]));
att = Rcp_pp((q * d + l) * d + c);
}
// Ambient per light
{
Float4 lightAmbient = *Pointer<Float4>(data + OFFSET(DrawData,ff.lightAmbient[i])); // FIXME: Unpack
ambient.x = ambient.x + lightAmbient.x * att;
ambient.y = ambient.y + lightAmbient.y * att;
ambient.z = ambient.z + lightAmbient.z * att;
}
// Diffuse
if(state.vertexNormalActive)
{
Float4 dot;
dot = dot3(L, normal);
dot = Max(dot, Float4(0.0f));
dot *= att;
Vector4f diff;
if(state.vertexDiffuseMaterialSourceActive == MATERIAL_MATERIAL)
{
diff.x = diff.y = diff.z = *Pointer<Float4>(data + OFFSET(DrawData,ff.materialDiffuse)); // FIXME: Unpack
diff.x = diff.x.xxxx;
diff.y = diff.y.yyyy;
diff.z = diff.z.zzzz;
}
else if(state.vertexDiffuseMaterialSourceActive == MATERIAL_COLOR1)
{
diff = v[Color0];
}
else if(state.vertexDiffuseMaterialSourceActive == MATERIAL_COLOR2)
{
diff = v[Color1];
}
else ASSERT(false);
Float4 lightDiffuse = *Pointer<Float4>(data + OFFSET(DrawData,ff.lightDiffuse[i]));
o[C0].x = o[C0].x + diff.x * dot * lightDiffuse.x; // FIXME: Clamp first?
o[C0].y = o[C0].y + diff.y * dot * lightDiffuse.y; // FIXME: Clamp first?
o[C0].z = o[C0].z + diff.z * dot * lightDiffuse.z; // FIXME: Clamp first?
}
// Specular
if(state.vertexSpecularActive)
{
Vector4f S;
Vector4f C; // Camera vector
Float4 pow;
pow = *Pointer<Float>(data + OFFSET(DrawData,ff.materialShininess));
S.x = Float4(0.0f) - vertexPosition.x;
S.y = Float4(0.0f) - vertexPosition.y;
S.z = Float4(0.0f) - vertexPosition.z;
C = normalize(S);
S.x = L.x + C.x;
S.y = L.y + C.y;
S.z = L.z + C.z;
C = normalize(S);
Float4 dot = Max(dot3(C, normal), Float4(0.0f)); // FIXME: max(dot3(C, normal), 0)
Float4 P = power(dot, pow);
P *= att;
Vector4f spec;
if(state.vertexSpecularMaterialSourceActive == MATERIAL_MATERIAL)
{
Float4 materialSpecular = *Pointer<Float4>(data + OFFSET(DrawData,ff.materialSpecular)); // FIXME: Unpack
spec.x = materialSpecular.x;
spec.y = materialSpecular.y;
spec.z = materialSpecular.z;
}
else if(state.vertexSpecularMaterialSourceActive == MATERIAL_COLOR1)
{
spec = v[Color0];
}
else if(state.vertexSpecularMaterialSourceActive == MATERIAL_COLOR2)
{
spec = v[Color1];
}
else ASSERT(false);
Float4 lightSpecular = *Pointer<Float4>(data + OFFSET(DrawData,ff.lightSpecular[i]));
spec.x *= lightSpecular.x;
spec.y *= lightSpecular.y;
spec.z *= lightSpecular.z;
spec.x *= P;
spec.y *= P;
spec.z *= P;
spec.x = Max(spec.x, Float4(0.0f));
spec.y = Max(spec.y, Float4(0.0f));
spec.z = Max(spec.z, Float4(0.0f));
if(secondaryColor)
{
o[C1].x = o[C1].x + spec.x;
o[C1].y = o[C1].y + spec.y;
o[C1].z = o[C1].z + spec.z;
}
else
{
o[C0].x = o[C0].x + spec.x;
o[C0].y = o[C0].y + spec.y;
o[C0].z = o[C0].z + spec.z;
}
}
}
if(state.vertexAmbientMaterialSourceActive == MATERIAL_MATERIAL)
{
Float4 materialAmbient = *Pointer<Float4>(data + OFFSET(DrawData,ff.materialAmbient)); // FIXME: Unpack
ambient.x = ambient.x * materialAmbient.x;
ambient.y = ambient.y * materialAmbient.y;
ambient.z = ambient.z * materialAmbient.z;
}
else if(state.vertexAmbientMaterialSourceActive == MATERIAL_COLOR1)
{
Vector4f materialDiffuse = v[Color0];
ambient.x = ambient.x * materialDiffuse.x;
ambient.y = ambient.y * materialDiffuse.y;
ambient.z = ambient.z * materialDiffuse.z;
}
else if(state.vertexAmbientMaterialSourceActive == MATERIAL_COLOR2)
{
Vector4f materialSpecular = v[Color1];
ambient.x = ambient.x * materialSpecular.x;
ambient.y = ambient.y * materialSpecular.y;
ambient.z = ambient.z * materialSpecular.z;
}
else ASSERT(false);
o[C0].x = o[C0].x + ambient.x;
o[C0].y = o[C0].y + ambient.y;
o[C0].z = o[C0].z + ambient.z;
// Emissive
if(state.vertexEmissiveMaterialSourceActive == MATERIAL_MATERIAL)
{
Float4 materialEmission = *Pointer<Float4>(data + OFFSET(DrawData,ff.materialEmission)); // FIXME: Unpack
o[C0].x = o[C0].x + materialEmission.x;
o[C0].y = o[C0].y + materialEmission.y;
o[C0].z = o[C0].z + materialEmission.z;
}
else if(state.vertexEmissiveMaterialSourceActive == MATERIAL_COLOR1)
{
Vector4f materialSpecular = v[Color0];
o[C0].x = o[C0].x + materialSpecular.x;
o[C0].y = o[C0].y + materialSpecular.y;
o[C0].z = o[C0].z + materialSpecular.z;
}
else if(state.vertexEmissiveMaterialSourceActive == MATERIAL_COLOR2)
{
Vector4f materialSpecular = v[Color1];
o[C0].x = o[C0].x + materialSpecular.x;
o[C0].y = o[C0].y + materialSpecular.y;
o[C0].z = o[C0].z + materialSpecular.z;
}
else ASSERT(false);
// Diffuse alpha component
if(state.vertexDiffuseMaterialSourceActive == MATERIAL_MATERIAL)
{
o[C0].w = Float4(*Pointer<Float4>(data + OFFSET(DrawData,ff.materialDiffuse[0]))).wwww; // FIXME: Unpack
}
else if(state.vertexDiffuseMaterialSourceActive == MATERIAL_COLOR1)
{
Vector4f alpha = v[Color0];
o[C0].w = alpha.w;
}
else if(state.vertexDiffuseMaterialSourceActive == MATERIAL_COLOR2)
{
Vector4f alpha = v[Color1];
o[C0].w = alpha.w;
}
else ASSERT(false);
if(state.vertexSpecularActive)
{
// Specular alpha component
if(state.vertexSpecularMaterialSourceActive == MATERIAL_MATERIAL)
{
o[C1].w = Float4(*Pointer<Float4>(data + OFFSET(DrawData,ff.materialSpecular[3]))).wwww; // FIXME: Unpack
}
else if(state.vertexSpecularMaterialSourceActive == MATERIAL_COLOR1)
{
Vector4f alpha = v[Color0];
o[C1].w = alpha.w;
}
else if(state.vertexSpecularMaterialSourceActive == MATERIAL_COLOR2)
{
Vector4f alpha = v[Color1];
o[C1].w = alpha.w;
}
else ASSERT(false);
}
}
if(state.fogActive)
{
Float4 f;
if(!state.rangeFogActive)
{
f = Abs(vertexPosition.z);
}
else
{
f = Sqrt(dot3(vertexPosition, vertexPosition)); // FIXME: f = length(vertexPosition);
}
switch(state.vertexFogMode)
{
case FOG_NONE:
if(state.specularActive)
{
o[Fog].x = o[C1].w;
}
else
{
o[Fog].x = Float4(0.0f);
}
break;
case FOG_LINEAR:
o[Fog].x = f * *Pointer<Float4>(data + OFFSET(DrawData,fog.scale)) + *Pointer<Float4>(data + OFFSET(DrawData,fog.offset));
break;
case FOG_EXP:
o[Fog].x = exponential2(f * *Pointer<Float4>(data + OFFSET(DrawData,fog.densityE)), true);
break;
case FOG_EXP2:
o[Fog].x = exponential2((f * f) * *Pointer<Float4>(data + OFFSET(DrawData,fog.density2E)), true);
break;
default:
ASSERT(false);
}
}
for(int stage = 0; stage < 8; stage++)
{
processTextureCoordinate(stage, normal, position);
}
processPointSize();
}
void VertexPipeline::processTextureCoordinate(int stage, Vector4f &normal, Vector4f &position)
{
if(state.output[T0 + stage].write)
{
int i = state.textureState[stage].texCoordIndexActive;
switch(state.textureState[stage].texGenActive)
{
case TEXGEN_NONE:
{
Vector4f &&varying = v[TexCoord0 + i];
o[T0 + stage].x = varying.x;
o[T0 + stage].y = varying.y;
o[T0 + stage].z = varying.z;
o[T0 + stage].w = varying.w;
}
break;
case TEXGEN_PASSTHRU:
{
Vector4f &&varying = v[TexCoord0 + i];
o[T0 + stage].x = varying.x;
o[T0 + stage].y = varying.y;
o[T0 + stage].z = varying.z;
o[T0 + stage].w = varying.w;
if(state.input[TexCoord0 + i])
{
switch(state.input[TexCoord0 + i].count)
{
case 1:
o[T0 + stage].y = Float4(1.0f);
o[T0 + stage].z = Float4(0.0f);
o[T0 + stage].w = Float4(0.0f);
break;
case 2:
o[T0 + stage].z = Float4(1.0f);
o[T0 + stage].w = Float4(0.0f);
break;
case 3:
o[T0 + stage].w = Float4(1.0f);
break;
case 4:
break;
default:
ASSERT(false);
}
}
}
break;
case TEXGEN_NORMAL:
{
Vector4f Nc; // Normal vector in camera space
if(state.vertexNormalActive)
{
Nc = normal;
}
else
{
Nc.x = Float4(0.0f);
Nc.y = Float4(0.0f);
Nc.z = Float4(0.0f);
}
Nc.w = Float4(1.0f);
o[T0 + stage].x = Nc.x;
o[T0 + stage].y = Nc.y;
o[T0 + stage].z = Nc.z;
o[T0 + stage].w = Nc.w;
}
break;
case TEXGEN_POSITION:
{
Vector4f Pn = transformBlend(v[Position], Pointer<Byte>(data + OFFSET(DrawData,ff.cameraTransformT)), true); // Position in camera space
Pn.w = Float4(1.0f);
o[T0 + stage].x = Pn.x;
o[T0 + stage].y = Pn.y;
o[T0 + stage].z = Pn.z;
o[T0 + stage].w = Pn.w;
}
break;
case TEXGEN_REFLECTION:
{
Vector4f R; // Reflection vector
if(state.vertexNormalActive)
{
Vector4f Nc; // Normal vector in camera space
Nc = normal;
if(state.localViewerActive)
{
Vector4f Ec; // Eye vector in camera space
Vector4f N2;
Ec = transformBlend(v[Position], Pointer<Byte>(data + OFFSET(DrawData,ff.cameraTransformT)), true);
Ec = normalize(Ec);
// R = E - 2 * N * (E . N)
Float4 dot = Float4(2.0f) * dot3(Ec, Nc);
R.x = Ec.x - Nc.x * dot;
R.y = Ec.y - Nc.y * dot;
R.z = Ec.z - Nc.z * dot;
}
else
{
// u = -2 * Nz * Nx
// v = -2 * Nz * Ny
// w = 1 - 2 * Nz * Nz
R.x = -Float4(2.0f) * Nc.z * Nc.x;
R.y = -Float4(2.0f) * Nc.z * Nc.y;
R.z = Float4(1.0f) - Float4(2.0f) * Nc.z * Nc.z;
}
}
else
{
R.x = Float4(0.0f);
R.y = Float4(0.0f);
R.z = Float4(0.0f);
}
R.w = Float4(1.0f);
o[T0 + stage].x = R.x;
o[T0 + stage].y = R.y;
o[T0 + stage].z = R.z;
o[T0 + stage].w = R.w;
}
break;
case TEXGEN_SPHEREMAP:
{
Vector4f R; // Reflection vector
if(state.vertexNormalActive)
{
Vector4f Nc; // Normal vector in camera space
Nc = normal;
if(state.localViewerActive)
{
Vector4f Ec; // Eye vector in camera space
Vector4f N2;
Ec = transformBlend(v[Position], Pointer<Byte>(data + OFFSET(DrawData,ff.cameraTransformT)), true);
Ec = normalize(Ec);
// R = E - 2 * N * (E . N)
Float4 dot = Float4(2.0f) * dot3(Ec, Nc);
R.x = Ec.x - Nc.x * dot;
R.y = Ec.y - Nc.y * dot;
R.z = Ec.z - Nc.z * dot;
}
else
{
// u = -2 * Nz * Nx
// v = -2 * Nz * Ny
// w = 1 - 2 * Nz * Nz
R.x = -Float4(2.0f) * Nc.z * Nc.x;
R.y = -Float4(2.0f) * Nc.z * Nc.y;
R.z = Float4(1.0f) - Float4(2.0f) * Nc.z * Nc.z;
}
}
else
{
R.x = Float4(0.0f);
R.y = Float4(0.0f);
R.z = Float4(0.0f);
}
R.z -= Float4(1.0f);
R = normalize(R);
R.x = Float4(0.5f) * R.x + Float4(0.5f);
R.y = Float4(0.5f) * R.y + Float4(0.5f);
R.z = Float4(1.0f);
R.w = Float4(0.0f);
o[T0 + stage].x = R.x;
o[T0 + stage].y = R.y;
o[T0 + stage].z = R.z;
o[T0 + stage].w = R.w;
}
break;
default:
ASSERT(false);
}
Vector4f texTrans0;
Vector4f texTrans1;
Vector4f texTrans2;
Vector4f texTrans3;
Vector4f T;
Vector4f t;
T.x = o[T0 + stage].x;
T.y = o[T0 + stage].y;
T.z = o[T0 + stage].z;
T.w = o[T0 + stage].w;
switch(state.textureState[stage].textureTransformCountActive)
{
case 4:
texTrans3.x = texTrans3.y = texTrans3.z = texTrans3.w = *Pointer<Float4>(data + OFFSET(DrawData,ff.textureTransform[stage][3])); // FIXME: Unpack
texTrans3.x = texTrans3.x.xxxx;
texTrans3.y = texTrans3.y.yyyy;
texTrans3.z = texTrans3.z.zzzz;
texTrans3.w = texTrans3.w.wwww;
t.w = dot4(T, texTrans3);
case 3:
texTrans2.x = texTrans2.y = texTrans2.z = texTrans2.w = *Pointer<Float4>(data + OFFSET(DrawData,ff.textureTransform[stage][2])); // FIXME: Unpack
texTrans2.x = texTrans2.x.xxxx;
texTrans2.y = texTrans2.y.yyyy;
texTrans2.z = texTrans2.z.zzzz;
texTrans2.w = texTrans2.w.wwww;
t.z = dot4(T, texTrans2);
case 2:
texTrans1.x = texTrans1.y = texTrans1.z = texTrans1.w = *Pointer<Float4>(data + OFFSET(DrawData,ff.textureTransform[stage][1])); // FIXME: Unpack
texTrans1.x = texTrans1.x.xxxx;
texTrans1.y = texTrans1.y.yyyy;
texTrans1.z = texTrans1.z.zzzz;
texTrans1.w = texTrans1.w.wwww;
t.y = dot4(T, texTrans1);
case 1:
texTrans0.x = texTrans0.y = texTrans0.z = texTrans0.w = *Pointer<Float4>(data + OFFSET(DrawData,ff.textureTransform[stage][0])); // FIXME: Unpack
texTrans0.x = texTrans0.x.xxxx;
texTrans0.y = texTrans0.y.yyyy;
texTrans0.z = texTrans0.z.zzzz;
texTrans0.w = texTrans0.w.wwww;
t.x = dot4(T, texTrans0);
o[T0 + stage].x = t.x;
o[T0 + stage].y = t.y;
o[T0 + stage].z = t.z;
o[T0 + stage].w = t.w;
case 0:
break;
default:
ASSERT(false);
}
}
}
void VertexPipeline::processPointSize()
{
if(!state.pointSizeActive)
{
return; // Use global pointsize
}
if(state.input[PointSize])
{
o[Pts].y = v[PointSize].x;
}
else
{
o[Pts].y = *Pointer<Float4>(data + OFFSET(DrawData,point.pointSize));
}
if(state.pointScaleActive && !state.preTransformed)
{
Vector4f p = transformBlend(v[Position], Pointer<Byte>(data + OFFSET(DrawData,ff.cameraTransformT)), true);
Float4 d = Sqrt(dot3(p, p)); // FIXME: length(p);
Float4 A = *Pointer<Float>(data + OFFSET(DrawData,point.pointScaleA)); // FIXME: Unpack
Float4 B = *Pointer<Float>(data + OFFSET(DrawData,point.pointScaleB)); // FIXME: Unpack
Float4 C = *Pointer<Float>(data + OFFSET(DrawData,point.pointScaleC)); // FIXME: Unpack
A = RcpSqrt_pp(A + d * (B + d * C));
o[Pts].y = o[Pts].y * Float4(*Pointer<Float>(data + OFFSET(DrawData,viewportHeight))) * A; // FIXME: Unpack
}
}
Vector4f VertexPipeline::transform(const Register &src, const Pointer<Byte> &matrix, bool homogeneous)
{
Vector4f dst;
if(homogeneous)
{
Float4 m[4][4];
for(int j = 0; j < 4; j++)
{
for(int i = 0; i < 4; i++)
{
m[j][i].x = *Pointer<Float>(matrix + 16 * i + 4 * j);
m[j][i].y = *Pointer<Float>(matrix + 16 * i + 4 * j);
m[j][i].z = *Pointer<Float>(matrix + 16 * i + 4 * j);
m[j][i].w = *Pointer<Float>(matrix + 16 * i + 4 * j);
}
}
dst.x = src.x * m[0][0] + src.y * m[0][1] + src.z * m[0][2] + src.w * m[0][3];
dst.y = src.x * m[1][0] + src.y * m[1][1] + src.z * m[1][2] + src.w * m[1][3];
dst.z = src.x * m[2][0] + src.y * m[2][1] + src.z * m[2][2] + src.w * m[2][3];
dst.w = src.x * m[3][0] + src.y * m[3][1] + src.z * m[3][2] + src.w * m[3][3];
}
else
{
Float4 m[3][3];
for(int j = 0; j < 3; j++)
{
for(int i = 0; i < 3; i++)
{
m[j][i].x = *Pointer<Float>(matrix + 16 * i + 4 * j);
m[j][i].y = *Pointer<Float>(matrix + 16 * i + 4 * j);
m[j][i].z = *Pointer<Float>(matrix + 16 * i + 4 * j);
m[j][i].w = *Pointer<Float>(matrix + 16 * i + 4 * j);
}
}
dst.x = src.x * m[0][0] + src.y * m[0][1] + src.z * m[0][2];
dst.y = src.x * m[1][0] + src.y * m[1][1] + src.z * m[1][2];
dst.z = src.x * m[2][0] + src.y * m[2][1] + src.z * m[2][2];
}
return dst;
}
Vector4f VertexPipeline::transform(const Register &src, const Pointer<Byte> &matrix, UInt index[4], bool homogeneous)
{
Vector4f dst;
if(homogeneous)
{
Float4 m[4][4];
for(int j = 0; j < 4; j++)
{
for(int i = 0; i < 4; i++)
{
m[j][i].x = *Pointer<Float>(matrix + 16 * i + 4 * j + index[0]);
m[j][i].y = *Pointer<Float>(matrix + 16 * i + 4 * j + index[1]);
m[j][i].z = *Pointer<Float>(matrix + 16 * i + 4 * j + index[2]);
m[j][i].w = *Pointer<Float>(matrix + 16 * i + 4 * j + index[3]);
}
}
dst.x = src.x * m[0][0] + src.y * m[0][1] + src.z * m[0][2] + m[0][3];
dst.y = src.x * m[1][0] + src.y * m[1][1] + src.z * m[1][2] + m[1][3];
dst.z = src.x * m[2][0] + src.y * m[2][1] + src.z * m[2][2] + m[2][3];
dst.w = src.x * m[3][0] + src.y * m[3][1] + src.z * m[3][2] + m[3][3];
}
else
{
Float4 m[3][3];
for(int j = 0; j < 3; j++)
{
for(int i = 0; i < 3; i++)
{
m[j][i].x = *Pointer<Float>(matrix + 16 * i + 4 * j + index[0]);
m[j][i].y = *Pointer<Float>(matrix + 16 * i + 4 * j + index[1]);
m[j][i].z = *Pointer<Float>(matrix + 16 * i + 4 * j + index[2]);
m[j][i].w = *Pointer<Float>(matrix + 16 * i + 4 * j + index[3]);
}
}
dst.x = src.x * m[0][0] + src.y * m[0][1] + src.z * m[0][2];
dst.y = src.x * m[1][0] + src.y * m[1][1] + src.z * m[1][2];
dst.z = src.x * m[2][0] + src.y * m[2][1] + src.z * m[2][2];
}
return dst;
}
Vector4f VertexPipeline::normalize(Vector4f &src)
{
Vector4f dst;
Float4 rcpLength = RcpSqrt_pp(dot3(src, src));
dst.x = src.x * rcpLength;
dst.y = src.y * rcpLength;
dst.z = src.z * rcpLength;
return dst;
}
Float4 VertexPipeline::power(Float4 &src0, Float4 &src1)
{
Float4 dst = src0;
dst = dst * dst;
dst = dst * dst;
dst = Float4(As<Int4>(dst) - As<Int4>(Float4(1.0f)));
dst *= src1;
dst = As<Float4>(Int4(dst) + As<Int4>(Float4(1.0f)));
dst = RcpSqrt_pp(dst);
dst = RcpSqrt_pp(dst);
return dst;
}
}