src/Pipeline/SetupRoutine.cpp - SwiftShader - Git at Google

 // 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 "SetupRoutine.hpp"

 #include "Constants.hpp"
 #include "Device/Polygon.hpp"
 #include "Device/Primitive.hpp"
 #include "Device/Renderer.hpp"
 #include "Device/Vertex.hpp"
 #include "Reactor/Reactor.hpp"
 #include "Vulkan/VkDevice.hpp"

 namespace sw {

 SetupRoutine::SetupRoutine(const SetupProcessor::State &state)
     : state(state)
 {
 }

 SetupRoutine::~SetupRoutine()
 {
 }

 void SetupRoutine::generate()
 {
 	SetupFunction function;
 	{
 		Pointer<Byte> device(function.Arg<0>());
 		Pointer<Byte> primitive(function.Arg<1>());
 		Pointer<Byte> tri(function.Arg<2>());
 		Pointer<Byte> polygon(function.Arg<3>());
 		Pointer<Byte> data(function.Arg<4>());

 		Pointer<Byte> constants = device + OFFSET(vk::Device, constants);

 		const bool point = state.isDrawPoint;
 		const bool line = state.isDrawLine;
 		const bool triangle = state.isDrawTriangle;

 		const int V0 = OFFSET(Triangle, v0);
 		const int V1 = (triangle || line) ? OFFSET(Triangle, v1) : OFFSET(Triangle, v0);
 		const int V2 = triangle ? OFFSET(Triangle, v2) : (line ? OFFSET(Triangle, v1) : OFFSET(Triangle, v0));

 		Pointer<Byte> v0 = tri + V0;
 		Pointer<Byte> v1 = tri + V1;
 		Pointer<Byte> v2 = tri + V2;

 		Array<Int> X(16);
 		Array<Int> Y(16);

 		X[0] = *Pointer<Int>(v0 + OFFSET(Vertex, projected.x));
 		X[1] = *Pointer<Int>(v1 + OFFSET(Vertex, projected.x));
 		X[2] = *Pointer<Int>(v2 + OFFSET(Vertex, projected.x));

 		Y[0] = *Pointer<Int>(v0 + OFFSET(Vertex, projected.y));
 		Y[1] = *Pointer<Int>(v1 + OFFSET(Vertex, projected.y));
 		Y[2] = *Pointer<Int>(v2 + OFFSET(Vertex, projected.y));

 		Int d = 1;  // Winding direction

 		// Culling
 		if(triangle)
 		{
 			Float x0 = Float(X[0]);
 			Float x1 = Float(X[1]);
 			Float x2 = Float(X[2]);

 			Float y0 = Float(Y[0]);
 			Float y1 = Float(Y[1]);
 			Float y2 = Float(Y[2]);

 			Float A = (y0 - y2) * x1 + (y2 - y1) * x0 + (y1 - y0) * x2;  // Area

 			Int w0w1w2 = *Pointer<Int>(v0 + OFFSET(Vertex, w)) ^
 			             *Pointer<Int>(v1 + OFFSET(Vertex, w)) ^
 			             *Pointer<Int>(v2 + OFFSET(Vertex, w));

 			A = IfThenElse(w0w1w2 < 0, -A, A);

 			Bool frontFacing = (state.frontFace == VK_FRONT_FACE_COUNTER_CLOCKWISE) ? (A >= 0.0f) : (A <= 0.0f);

 			if(state.cullMode & VK_CULL_MODE_FRONT_BIT)
 			{
 				If(frontFacing) Return(0);
 			}
 			if(state.cullMode & VK_CULL_MODE_BACK_BIT)
 			{
 				If(!frontFacing) Return(0);
 			}

 			d = IfThenElse(A > 0.0f, d, Int(0));

 			If(frontFacing)
 			{
 				*Pointer<Byte8>(primitive + OFFSET(Primitive, clockwiseMask)) = Byte8(0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF);
 				*Pointer<Byte8>(primitive + OFFSET(Primitive, invClockwiseMask)) = Byte8(0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00);
 			}
 			Else
 			{
 				*Pointer<Byte8>(primitive + OFFSET(Primitive, clockwiseMask)) = Byte8(0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00);
 				*Pointer<Byte8>(primitive + OFFSET(Primitive, invClockwiseMask)) = Byte8(0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF);
 			}
 		}
 		else
 		{
 			*Pointer<Byte8>(primitive + OFFSET(Primitive, clockwiseMask)) = Byte8(0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF);
 			*Pointer<Byte8>(primitive + OFFSET(Primitive, invClockwiseMask)) = Byte8(0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00);
 		}

 		Int n = *Pointer<Int>(polygon + OFFSET(Polygon, n));
 		Int m = *Pointer<Int>(polygon + OFFSET(Polygon, i));

 		If(m != 0 || Bool(!triangle))  // Clipped triangle; reproject
 		{
 			Pointer<Byte> V = polygon + OFFSET(Polygon, P) + m * sizeof(void *) * 16;

 			Int i = 0;

 			Do
 			{
 				Pointer<Float4> p = *Pointer<Pointer<Float4> >(V + i * sizeof(void *));
 				Float4 v = *Pointer<Float4>(p, 16);

 				Float w = v.w;
 				Float rhw = IfThenElse(w != 0.0f, 1.0f / w, Float(1.0f));

 				X[i] = RoundInt(*Pointer<Float>(data + OFFSET(DrawData, X0xF)) + v.x * rhw * *Pointer<Float>(data + OFFSET(DrawData, WxF)));
 				Y[i] = RoundInt(*Pointer<Float>(data + OFFSET(DrawData, Y0xF)) + v.y * rhw * *Pointer<Float>(data + OFFSET(DrawData, HxF)));

 				i++;
 			}
 			Until(i >= n);
 		}

 		// Vertical range
 		Int yMin = Y[0];
 		Int yMax = Y[0];

 		Int i = 1;

 		Do
 		{
 			yMin = Min(Y[i], yMin);
 			yMax = Max(Y[i], yMax);

 			i++;
 		}
 		Until(i >= n);

 		constexpr int subPixB = vk::SUBPIXEL_PRECISION_BITS;
 		constexpr int subPixM = vk::SUBPIXEL_PRECISION_MASK;
 		constexpr float subPixF = vk::SUBPIXEL_PRECISION_FACTOR;

 		if(state.enableMultiSampling)
 		{
 			yMin = (yMin + Constants::yMinMultiSampleOffset) >> subPixB;
 			yMax = (yMax + Constants::yMaxMultiSampleOffset) >> subPixB;
 		}
 		else
 		{
 			yMin = (yMin + subPixM) >> subPixB;
 			yMax = (yMax + subPixM) >> subPixB;
 		}

 		yMin = Max(yMin, *Pointer<Int>(data + OFFSET(DrawData, scissorY0)));
 		yMax = Min(yMax, *Pointer<Int>(data + OFFSET(DrawData, scissorY1)));

 		// If yMin and yMax are initially negative, the scissor clamping above will typically result
 		// in yMin == 0 and yMax unchanged. We bail as we don't need to rasterize this primitive, and
 		// code below assumes yMin < yMax.
 		If(yMin >= yMax)
 		{
 			Return(0);
 		}

 		For(Int q = 0, q < state.multiSampleCount, q++)
 		{
 			Array<Int> Xq(16);
 			Array<Int> Yq(16);

 			Int i = 0;

 			Do
 			{
 				Xq[i] = X[i];
 				Yq[i] = Y[i];

 				if(state.enableMultiSampling)
 				{
 					// The subtraction here is because we're not moving the point, we're testing the edge against it
 					Xq[i] = Xq[i] - *Pointer<Int>(constants + OFFSET(Constants, Xf) + q * sizeof(int));
 					Yq[i] = Yq[i] - *Pointer<Int>(constants + OFFSET(Constants, Yf) + q * sizeof(int));
 				}

 				i++;
 			}
 			Until(i >= n);

 			Pointer<Byte> leftEdge = Pointer<Byte>(primitive + OFFSET(Primitive, outline->left)) + q * sizeof(Primitive);
 			Pointer<Byte> rightEdge = Pointer<Byte>(primitive + OFFSET(Primitive, outline->right)) + q * sizeof(Primitive);

 			if(state.enableMultiSampling)
 			{
 				Int xMin = *Pointer<Int>(data + OFFSET(DrawData, scissorX0));
 				Int xMax = *Pointer<Int>(data + OFFSET(DrawData, scissorX1));
 				Short x = Short(Clamp((X[0] + subPixM) >> subPixB, xMin, xMax));

 				For(Int y = yMin - 1, y < yMax + 1, y++)
 				{
 					*Pointer<Short>(leftEdge + y * sizeof(Primitive::Span)) = x;
 					*Pointer<Short>(rightEdge + y * sizeof(Primitive::Span)) = x;
 				}
 			}

 			Xq[n] = Xq[0];
 			Yq[n] = Yq[0];

 			// Rasterize
 			{
 				Int i = 0;

 				Do
 				{
 					edge(primitive, data, Xq[i + 1 - d], Yq[i + 1 - d], Xq[i + d], Yq[i + d], q);

 					i++;
 				}
 				Until(i >= n);
 			}

 			if(!state.enableMultiSampling)
 			{
 				For(, yMin < yMax && *Pointer<Short>(leftEdge + yMin * sizeof(Primitive::Span)) == *Pointer<Short>(rightEdge + yMin * sizeof(Primitive::Span)), yMin++)
 				{
 					// Increments yMin
 				}

 				For(, yMax > yMin && *Pointer<Short>(leftEdge + (yMax - 1) * sizeof(Primitive::Span)) == *Pointer<Short>(rightEdge + (yMax - 1) * sizeof(Primitive::Span)), yMax--)
 				{
 					// Decrements yMax
 				}

 				If(yMin == yMax)
 				{
 					Return(0);
 				}

 				*Pointer<Short>(leftEdge + (yMin - 1) * sizeof(Primitive::Span)) = *Pointer<Short>(leftEdge + yMin * sizeof(Primitive::Span));
 				*Pointer<Short>(rightEdge + (yMin - 1) * sizeof(Primitive::Span)) = *Pointer<Short>(leftEdge + yMin * sizeof(Primitive::Span));
 				*Pointer<Short>(leftEdge + yMax * sizeof(Primitive::Span)) = *Pointer<Short>(leftEdge + (yMax - 1) * sizeof(Primitive::Span));
 				*Pointer<Short>(rightEdge + yMax * sizeof(Primitive::Span)) = *Pointer<Short>(leftEdge + (yMax - 1) * sizeof(Primitive::Span));
 			}
 		}

 		*Pointer<Int>(primitive + OFFSET(Primitive, yMin)) = yMin;
 		*Pointer<Int>(primitive + OFFSET(Primitive, yMax)) = yMax;

 		// Sort by minimum y
 		if(triangle)
 		{
 			Float y0 = *Pointer<Float>(v0 + OFFSET(Vertex, y));
 			Float y1 = *Pointer<Float>(v1 + OFFSET(Vertex, y));
 			Float y2 = *Pointer<Float>(v2 + OFFSET(Vertex, y));

 			Float yMin = Min(Min(y0, y1), y2);

 			conditionalRotate1(yMin == y1, v0, v1, v2);
 			conditionalRotate2(yMin == y2, v0, v1, v2);
 		}

 		// Sort by maximum w
 		if(triangle)
 		{
 			Float w0 = *Pointer<Float>(v0 + OFFSET(Vertex, w));
 			Float w1 = *Pointer<Float>(v1 + OFFSET(Vertex, w));
 			Float w2 = *Pointer<Float>(v2 + OFFSET(Vertex, w));

 			Float wMax = Max(Max(w0, w1), w2);

 			conditionalRotate1(wMax == w1, v0, v1, v2);
 			conditionalRotate2(wMax == w2, v0, v1, v2);
 		}

 		Float w0 = *Pointer<Float>(v0 + OFFSET(Vertex, w));
 		Float w1 = *Pointer<Float>(v1 + OFFSET(Vertex, w));
 		Float w2 = *Pointer<Float>(v2 + OFFSET(Vertex, w));

 		Float4 w012;

 		w012.x = w0;
 		w012.y = w1;
 		w012.z = w2;
 		w012.w = 1;

 		Float rhw0 = *Pointer<Float>(v0 + OFFSET(Vertex, projected.w));

 		Int X0 = *Pointer<Int>(v0 + OFFSET(Vertex, projected.x));
 		Int X1 = *Pointer<Int>(v1 + OFFSET(Vertex, projected.x));
 		Int X2 = *Pointer<Int>(v2 + OFFSET(Vertex, projected.x));

 		Int Y0 = *Pointer<Int>(v0 + OFFSET(Vertex, projected.y));
 		Int Y1 = *Pointer<Int>(v1 + OFFSET(Vertex, projected.y));
 		Int Y2 = *Pointer<Int>(v2 + OFFSET(Vertex, projected.y));

 		if(point)
 		{
 			*Pointer<Float>(primitive + OFFSET(Primitive, pointCoordX)) = Float(1.0f / subPixF) * Float(X0);
 			*Pointer<Float>(primitive + OFFSET(Primitive, pointCoordY)) = Float(1.0f / subPixF) * Float(Y0);
 		}

 		if(line)
 		{
 			X2 = X1 + Y1 - Y0;
 			Y2 = Y1 + X0 - X1;
 		}

 		Float dx = Float(X0) * (1.0f / subPixF);
 		Float dy = Float(Y0) * (1.0f / subPixF);

 		X1 -= X0;
 		Y1 -= Y0;

 		X2 -= X0;
 		Y2 -= Y0;

 		Float x1 = w1 * (1.0f / subPixF) * Float(X1);
 		Float y1 = w1 * (1.0f / subPixF) * Float(Y1);

 		Float x2 = w2 * (1.0f / subPixF) * Float(X2);
 		Float y2 = w2 * (1.0f / subPixF) * Float(Y2);

 		Float a = x1 * y2 - x2 * y1;

 		Float4 xQuad = Float4(0, 1, 0, 1) - Float4(dx);
 		Float4 yQuad = Float4(0, 0, 1, 1) - Float4(dy);

 		*Pointer<Float4>(primitive + OFFSET(Primitive, xQuad), 16) = xQuad;
 		*Pointer<Float4>(primitive + OFFSET(Primitive, yQuad), 16) = yQuad;

 		Float4 M[3];

 		M[0] = Float4(0, 0, 0, 0);
 		M[1] = Float4(0, 0, 0, 0);
 		M[2] = Float4(0, 0, 0, 0);

 		M[0].z = rhw0;

 		If(a != 0.0f)
 		{
 			Float A = 1.0f / a;
 			Float D = A * rhw0;

 			M[0].x = (y1 * w2 - y2 * w1) * D;
 			M[0].y = (x2 * w1 - x1 * w2) * D;
 			//	M[0].z = rhw0;
 			//	M[0].w = 0;

 			M[1].x = y2 * A;
 			M[1].y = -x2 * A;
 			//	M[1].z = 0;
 			//	M[1].w = 0;

 			M[2].x = -y1 * A;
 			M[2].y = x1 * A;
 			//	M[2].z = 0;
 			//	M[2].w = 0;
 		}

 		if(state.interpolateW)
 		{
 			Float4 ABC = M[0] + M[1] + M[2];

 			Float4 A = ABC.x;
 			Float4 B = ABC.y;
 			Float4 C = ABC.z;

 			*Pointer<Float4>(primitive + OFFSET(Primitive, w.A), 16) = A;
 			*Pointer<Float4>(primitive + OFFSET(Primitive, w.B), 16) = B;
 			*Pointer<Float4>(primitive + OFFSET(Primitive, w.C), 16) = C;
 		}

 		if(state.interpolateZ)
 		{
 			Float z0 = *Pointer<Float>(v0 + OFFSET(Vertex, projected.z));
 			Float z1 = *Pointer<Float>(v1 + OFFSET(Vertex, projected.z));
 			Float z2 = *Pointer<Float>(v2 + OFFSET(Vertex, projected.z));

 			z1 -= z0;
 			z2 -= z0;

 			Float A;
 			Float B;
 			Float C;

 			if(!point)
 			{
 				Float x1 = Float(X1) * (1.0f / subPixF);
 				Float y1 = Float(Y1) * (1.0f / subPixF);
 				Float x2 = Float(X2) * (1.0f / subPixF);
 				Float y2 = Float(Y2) * (1.0f / subPixF);

 				Float D = *Pointer<Float>(data + OFFSET(DrawData, depthRange)) / (x1 * y2 - x2 * y1);

 				A = (y2 * z1 - y1 * z2) * D;
 				B = (x1 * z2 - x2 * z1) * D;
 			}
 			else
 			{
 				A = 0.0f;
 				B = 0.0f;
 			}

 			C = z0 * *Pointer<Float>(data + OFFSET(DrawData, depthRange)) + *Pointer<Float>(data + OFFSET(DrawData, depthNear));

 			*Pointer<Float4>(primitive + OFFSET(Primitive, z.A), 16) = Float4(A);
 			*Pointer<Float4>(primitive + OFFSET(Primitive, z.B), 16) = Float4(B);
 			*Pointer<Float4>(primitive + OFFSET(Primitive, z.C), 16) = Float4(C);

 			Float bias = 0.0f;

 			if(state.applyConstantDepthBias)
 			{
 				Float r;  // Minimum resolvable difference

 				if(state.fixedPointDepthBuffer)
 				{
 					// TODO(b/139341727): Pre-multiply the constant depth bias factor by the minimum
 					// resolvable difference.

 					// TODO(b/139341727): When there's a fixed-point depth buffer and no depth bias clamp,
 					// the constant depth bias factor could be added to 'depthNear', eliminating the per-
 					// polygon addition.

 					r = *Pointer<Float>(data + OFFSET(DrawData, minimumResolvableDepthDifference));
 				}
 				else  // Floating-point depth buffer
 				{
 					// "For floating-point depth buffers, there is no single minimum resolvable difference.
 					//  In this case, the minimum resolvable difference for a given polygon is dependent on
 					//  the maximum exponent, e, in the range of z values spanned by the primitive. If n is
 					//  the number of bits in the floating-point mantissa, the minimum resolvable difference,
 					//  r, for the given primitive is defined as r = 2^(e-n)."

 					Float Z0 = C;
 					Float Z1 = z1 * *Pointer<Float>(data + OFFSET(DrawData, depthRange)) + *Pointer<Float>(data + OFFSET(DrawData, depthNear));
 					Float Z2 = z2 * *Pointer<Float>(data + OFFSET(DrawData, depthRange)) + *Pointer<Float>(data + OFFSET(DrawData, depthNear));

 					Int e0 = As<Int>(Z0) & 0x7F800000;
 					Int e1 = As<Int>(Z1) & 0x7F800000;
 					Int e2 = As<Int>(Z2) & 0x7F800000;

 					Int e = Max(Max(e0, e1), e2);

 					r = As<Float>(e) * Float(1.0f / (1 << 23));
 				}

 				bias = r * *Pointer<Float>(data + OFFSET(DrawData, constantDepthBias));
 			}

 			if(state.applySlopeDepthBias)
 			{
 				Float m = Max(Abs(A), Abs(B));

 				bias += m * *Pointer<Float>(data + OFFSET(DrawData, slopeDepthBias));  // TODO(b/155302798): Optimize 0 += x;
 			}

 			if(state.applyConstantDepthBias || state.applySlopeDepthBias)
 			{
 				if(state.applyDepthBiasClamp)
 				{
 					Float clamp = *Pointer<Float>(data + OFFSET(DrawData, depthBiasClamp));

 					bias = IfThenElse(clamp > 0.0f, Min(bias, clamp), Max(bias, clamp));
 				}

 				*Pointer<Float4>(primitive + OFFSET(Primitive, zBias), 16) = Float4(bias);
 			}
 		}

 		int packedInterpolant = 0;
 		for(int interfaceInterpolant = 0; interfaceInterpolant < MAX_INTERFACE_COMPONENTS; interfaceInterpolant++)
 		{
 			if(state.gradient[interfaceInterpolant].Type != SpirvShader::ATTRIBTYPE_UNUSED)
 			{
 				setupGradient(primitive, tri, w012, M, v0, v1, v2,
 				              OFFSET(Vertex, v[interfaceInterpolant]),
 				              OFFSET(Primitive, V[packedInterpolant]),
 				              state.gradient[interfaceInterpolant].Flat,
 				              !state.gradient[interfaceInterpolant].NoPerspective);
 				packedInterpolant++;
 			}
 		}

 		for(unsigned int i = 0; i < state.numClipDistances; i++)
 		{
 			setupGradient(primitive, tri, w012, M, v0, v1, v2,
 			              OFFSET(Vertex, clipDistance[i]),
 			              OFFSET(Primitive, clipDistance[i]),
 			              false, true);
 		}

 		for(unsigned int i = 0; i < state.numCullDistances; i++)
 		{
 			setupGradient(primitive, tri, w012, M, v0, v1, v2,
 			              OFFSET(Vertex, cullDistance[i]),
 			              OFFSET(Primitive, cullDistance[i]),
 			              false, true);
 		}

 		Return(1);
 	}

 	routine = function("SetupRoutine");
 }

 void SetupRoutine::setupGradient(Pointer<Byte> &primitive, Pointer<Byte> &triangle, Float4 &w012, Float4 (&m)[3], Pointer<Byte> &v0, Pointer<Byte> &v1, Pointer<Byte> &v2, int attribute, int planeEquation, bool flat, bool perspective)
 {
 	if(!flat)
 	{
 		Float4 i;
 		i.x = *Pointer<Float>(v0 + attribute);
 		i.y = *Pointer<Float>(v1 + attribute);
 		i.z = *Pointer<Float>(v2 + attribute);
 		i.w = 0;

 		if(!perspective)
 		{
 			i *= w012;
 		}

 		Float4 A = i.xxxx * m[0];
 		Float4 B = i.yyyy * m[1];
 		Float4 C = i.zzzz * m[2];

 		C = A + B + C;

 		A = C.xxxx;
 		B = C.yyyy;
 		C = C.zzzz;

 		*Pointer<Float4>(primitive + planeEquation + 0, 16) = A;
 		*Pointer<Float4>(primitive + planeEquation + 16, 16) = B;
 		*Pointer<Float4>(primitive + planeEquation + 32, 16) = C;
 	}
 	else
 	{
 		int leadingVertex = OFFSET(Triangle, v0);
 		Float C = *Pointer<Float>(triangle + leadingVertex + attribute);

 		*Pointer<Float4>(primitive + planeEquation + 0, 16) = Float4(0, 0, 0, 0);
 		*Pointer<Float4>(primitive + planeEquation + 16, 16) = Float4(0, 0, 0, 0);
 		*Pointer<Float4>(primitive + planeEquation + 32, 16) = Float4(C);
 	}
 }

 void SetupRoutine::edge(Pointer<Byte> &primitive, Pointer<Byte> &data, const Int &Xa, const Int &Ya, const Int &Xb, const Int &Yb, Int &q)
 {
 	If(Ya != Yb)
 	{
 		Bool swap = Yb < Ya;

 		Int X1 = IfThenElse(swap, Xb, Xa);
 		Int X2 = IfThenElse(swap, Xa, Xb);
 		Int Y1 = IfThenElse(swap, Yb, Ya);
 		Int Y2 = IfThenElse(swap, Ya, Yb);

 		constexpr int subPixB = vk::SUBPIXEL_PRECISION_BITS;
 		constexpr int subPixM = vk::SUBPIXEL_PRECISION_MASK;

 		Int y1 = Max((Y1 + subPixM) >> subPixB, *Pointer<Int>(data + OFFSET(DrawData, scissorY0)));
 		Int y2 = Min((Y2 + subPixM) >> subPixB, *Pointer<Int>(data + OFFSET(DrawData, scissorY1)));

 		If(y1 < y2)
 		{
 			Int xMin = *Pointer<Int>(data + OFFSET(DrawData, scissorX0));
 			Int xMax = *Pointer<Int>(data + OFFSET(DrawData, scissorX1));

 			Pointer<Byte> leftEdge = primitive + q * sizeof(Primitive) + OFFSET(Primitive, outline->left);
 			Pointer<Byte> rightEdge = primitive + q * sizeof(Primitive) + OFFSET(Primitive, outline->right);
 			Pointer<Byte> edge = IfThenElse(swap, rightEdge, leftEdge);

 			// Deltas
 			Int DX12 = X2 - X1;
 			Int DY12 = Y2 - Y1;

 			Int FDX12 = DX12 << subPixB;
 			Int FDY12 = DY12 << subPixB;

 			Int X = DX12 * ((y1 << subPixB) - Y1) + (X1 & subPixM) * DY12;
 			Int x = (X1 >> subPixB) + X / FDY12;  // Edge
 			Int d = X % FDY12;                    // Error-term
 			Int ceil = -d >> 31;                  // Ceiling division: remainder <= 0
 			x -= ceil;
 			d -= ceil & FDY12;

 			Int Q = FDX12 / FDY12;  // Edge-step
 			Int R = FDX12 % FDY12;  // Error-step
 			Int floor = R >> 31;    // Flooring division: remainder >= 0
 			Q += floor;
 			R += floor & FDY12;

 			Int D = FDY12;  // Error-overflow
 			Int y = y1;

 			Do
 			{
 				*Pointer<Short>(edge + y * sizeof(Primitive::Span)) = Short(Clamp(x, xMin, xMax));

 				x += Q;
 				d += R;

 				Int overflow = -d >> 31;

 				d -= D & overflow;
 				x -= overflow;

 				y++;
 			}
 			Until(y >= y2);
 		}
 	}
 }

 void SetupRoutine::conditionalRotate1(Bool condition, Pointer<Byte> &v0, Pointer<Byte> &v1, Pointer<Byte> &v2)
 {
 #if 0  // Rely on LLVM optimization
 		If(condition)
 		{
 			Pointer<Byte> vX;

 			vX = v0;
 			v0 = v1;
 			v1 = v2;
 			v2 = vX;
 		}
 #else
 	Pointer<Byte> vX = v0;
 	v0 = IfThenElse(condition, v1, v0);
 	v1 = IfThenElse(condition, v2, v1);
 	v2 = IfThenElse(condition, vX, v2);
 #endif
 }

 void SetupRoutine::conditionalRotate2(Bool condition, Pointer<Byte> &v0, Pointer<Byte> &v1, Pointer<Byte> &v2)
 {
 #if 0  // Rely on LLVM optimization
 		If(condition)
 		{
 			Pointer<Byte> vX;

 			vX = v2;
 			v2 = v1;
 			v1 = v0;
 			v0 = vX;
 		}
 #else
 	Pointer<Byte> vX = v2;
 	v2 = IfThenElse(condition, v1, v2);
 	v1 = IfThenElse(condition, v0, v1);
 	v0 = IfThenElse(condition, vX, v0);
 #endif
 }

 SetupFunction::RoutineType SetupRoutine::getRoutine()
 {
 	return routine;
 }

 }  // namespace sw
	// 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 "SetupRoutine.hpp"

	#include "Constants.hpp"
	#include "Device/Polygon.hpp"
	#include "Device/Primitive.hpp"
	#include "Device/Renderer.hpp"
	#include "Device/Vertex.hpp"
	#include "Reactor/Reactor.hpp"
	#include "Vulkan/VkDevice.hpp"

	namespace sw {

	SetupRoutine::SetupRoutine(const SetupProcessor::State &state)
	: state(state)
	{
	}

	SetupRoutine::~SetupRoutine()
	{
	}

	void SetupRoutine::generate()
	{
	SetupFunction function;
	{
	Pointer<Byte> device(function.Arg<0>());
	Pointer<Byte> primitive(function.Arg<1>());
	Pointer<Byte> tri(function.Arg<2>());
	Pointer<Byte> polygon(function.Arg<3>());
	Pointer<Byte> data(function.Arg<4>());

	Pointer<Byte> constants = device + OFFSET(vk::Device, constants);

	const bool point = state.isDrawPoint;
	const bool line = state.isDrawLine;
	const bool triangle = state.isDrawTriangle;

	const int V0 = OFFSET(Triangle, v0);
	const int V1 = (triangle \|\| line) ? OFFSET(Triangle, v1) : OFFSET(Triangle, v0);
	const int V2 = triangle ? OFFSET(Triangle, v2) : (line ? OFFSET(Triangle, v1) : OFFSET(Triangle, v0));

	Pointer<Byte> v0 = tri + V0;
	Pointer<Byte> v1 = tri + V1;
	Pointer<Byte> v2 = tri + V2;

	Array<Int> X(16);
	Array<Int> Y(16);

	X[0] = *Pointer<Int>(v0 + OFFSET(Vertex, projected.x));
	X[1] = *Pointer<Int>(v1 + OFFSET(Vertex, projected.x));
	X[2] = *Pointer<Int>(v2 + OFFSET(Vertex, projected.x));

	Y[0] = *Pointer<Int>(v0 + OFFSET(Vertex, projected.y));
	Y[1] = *Pointer<Int>(v1 + OFFSET(Vertex, projected.y));
	Y[2] = *Pointer<Int>(v2 + OFFSET(Vertex, projected.y));

	Int d = 1; // Winding direction

	// Culling
	if(triangle)
	{
	Float x0 = Float(X[0]);
	Float x1 = Float(X[1]);
	Float x2 = Float(X[2]);

	Float y0 = Float(Y[0]);
	Float y1 = Float(Y[1]);
	Float y2 = Float(Y[2]);

	Float A = (y0 - y2) * x1 + (y2 - y1) * x0 + (y1 - y0) * x2; // Area

	Int w0w1w2 = *Pointer<Int>(v0 + OFFSET(Vertex, w)) ^
	*Pointer<Int>(v1 + OFFSET(Vertex, w)) ^
	*Pointer<Int>(v2 + OFFSET(Vertex, w));

	A = IfThenElse(w0w1w2 < 0, -A, A);

	Bool frontFacing = (state.frontFace == VK_FRONT_FACE_COUNTER_CLOCKWISE) ? (A >= 0.0f) : (A <= 0.0f);

	if(state.cullMode & VK_CULL_MODE_FRONT_BIT)
	{
	If(frontFacing) Return(0);
	}
	if(state.cullMode & VK_CULL_MODE_BACK_BIT)
	{
	If(!frontFacing) Return(0);
	}

	d = IfThenElse(A > 0.0f, d, Int(0));

	If(frontFacing)
	{
	*Pointer<Byte8>(primitive + OFFSET(Primitive, clockwiseMask)) = Byte8(0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF);
	*Pointer<Byte8>(primitive + OFFSET(Primitive, invClockwiseMask)) = Byte8(0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00);
	}
	Else
	{
	*Pointer<Byte8>(primitive + OFFSET(Primitive, clockwiseMask)) = Byte8(0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00);
	*Pointer<Byte8>(primitive + OFFSET(Primitive, invClockwiseMask)) = Byte8(0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF);
	}
	}
	else
	{
	*Pointer<Byte8>(primitive + OFFSET(Primitive, clockwiseMask)) = Byte8(0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF);
	*Pointer<Byte8>(primitive + OFFSET(Primitive, invClockwiseMask)) = Byte8(0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00);
	}

	Int n = *Pointer<Int>(polygon + OFFSET(Polygon, n));
	Int m = *Pointer<Int>(polygon + OFFSET(Polygon, i));

	If(m != 0 \|\| Bool(!triangle)) // Clipped triangle; reproject
	{
	Pointer<Byte> V = polygon + OFFSET(Polygon, P) + m * sizeof(void ) 16;

	Int i = 0;

	Do
	{
	Pointer<Float4> p = Pointer<Pointer<Float4> >(V + i sizeof(void *));
	Float4 v = *Pointer<Float4>(p, 16);

	Float w = v.w;
	Float rhw = IfThenElse(w != 0.0f, 1.0f / w, Float(1.0f));

	X[i] = RoundInt(Pointer<Float>(data + OFFSET(DrawData, X0xF)) + v.x rhw * *Pointer<Float>(data + OFFSET(DrawData, WxF)));
	Y[i] = RoundInt(Pointer<Float>(data + OFFSET(DrawData, Y0xF)) + v.y rhw * *Pointer<Float>(data + OFFSET(DrawData, HxF)));

	i++;
	}
	Until(i >= n);
	}

	// Vertical range
	Int yMin = Y[0];
	Int yMax = Y[0];

	Int i = 1;

	Do
	{
	yMin = Min(Y[i], yMin);
	yMax = Max(Y[i], yMax);

	i++;
	}
	Until(i >= n);

	constexpr int subPixB = vk::SUBPIXEL_PRECISION_BITS;
	constexpr int subPixM = vk::SUBPIXEL_PRECISION_MASK;
	constexpr float subPixF = vk::SUBPIXEL_PRECISION_FACTOR;

	if(state.enableMultiSampling)
	{
	yMin = (yMin + Constants::yMinMultiSampleOffset) >> subPixB;
	yMax = (yMax + Constants::yMaxMultiSampleOffset) >> subPixB;
	}
	else
	{
	yMin = (yMin + subPixM) >> subPixB;
	yMax = (yMax + subPixM) >> subPixB;
	}

	yMin = Max(yMin, *Pointer<Int>(data + OFFSET(DrawData, scissorY0)));
	yMax = Min(yMax, *Pointer<Int>(data + OFFSET(DrawData, scissorY1)));

	// If yMin and yMax are initially negative, the scissor clamping above will typically result
	// in yMin == 0 and yMax unchanged. We bail as we don't need to rasterize this primitive, and
	// code below assumes yMin < yMax.
	If(yMin >= yMax)
	{
	Return(0);
	}

	For(Int q = 0, q < state.multiSampleCount, q++)
	{
	Array<Int> Xq(16);
	Array<Int> Yq(16);

	Int i = 0;

	Do
	{
	Xq[i] = X[i];
	Yq[i] = Y[i];

	if(state.enableMultiSampling)
	{
	// The subtraction here is because we're not moving the point, we're testing the edge against it
	Xq[i] = Xq[i] - Pointer<Int>(constants + OFFSET(Constants, Xf) + q sizeof(int));
	Yq[i] = Yq[i] - Pointer<Int>(constants + OFFSET(Constants, Yf) + q sizeof(int));
	}

	i++;
	}
	Until(i >= n);

	Pointer<Byte> leftEdge = Pointer<Byte>(primitive + OFFSET(Primitive, outline->left)) + q * sizeof(Primitive);
	Pointer<Byte> rightEdge = Pointer<Byte>(primitive + OFFSET(Primitive, outline->right)) + q * sizeof(Primitive);

	if(state.enableMultiSampling)
	{
	Int xMin = *Pointer<Int>(data + OFFSET(DrawData, scissorX0));
	Int xMax = *Pointer<Int>(data + OFFSET(DrawData, scissorX1));
	Short x = Short(Clamp((X[0] + subPixM) >> subPixB, xMin, xMax));

	For(Int y = yMin - 1, y < yMax + 1, y++)
	{
	Pointer<Short>(leftEdge + y sizeof(Primitive::Span)) = x;
	Pointer<Short>(rightEdge + y sizeof(Primitive::Span)) = x;
	}
	}

	Xq[n] = Xq[0];
	Yq[n] = Yq[0];

	// Rasterize
	{
	Int i = 0;

	Do
	{
	edge(primitive, data, Xq[i + 1 - d], Yq[i + 1 - d], Xq[i + d], Yq[i + d], q);

	i++;
	}
	Until(i >= n);
	}

	if(!state.enableMultiSampling)
	{
	For(, yMin < yMax && Pointer<Short>(leftEdge + yMin sizeof(Primitive::Span)) == Pointer<Short>(rightEdge + yMin sizeof(Primitive::Span)), yMin++)
	{
	// Increments yMin
	}

	For(, yMax > yMin && Pointer<Short>(leftEdge + (yMax - 1) sizeof(Primitive::Span)) == Pointer<Short>(rightEdge + (yMax - 1) sizeof(Primitive::Span)), yMax--)
	{
	// Decrements yMax
	}

	If(yMin == yMax)
	{
	Return(0);
	}

	Pointer<Short>(leftEdge + (yMin - 1) sizeof(Primitive::Span)) = Pointer<Short>(leftEdge + yMin sizeof(Primitive::Span));
	Pointer<Short>(rightEdge + (yMin - 1) sizeof(Primitive::Span)) = Pointer<Short>(leftEdge + yMin sizeof(Primitive::Span));
	Pointer<Short>(leftEdge + yMax sizeof(Primitive::Span)) = Pointer<Short>(leftEdge + (yMax - 1) sizeof(Primitive::Span));
	Pointer<Short>(rightEdge + yMax sizeof(Primitive::Span)) = Pointer<Short>(leftEdge + (yMax - 1) sizeof(Primitive::Span));
	}
	}

	*Pointer<Int>(primitive + OFFSET(Primitive, yMin)) = yMin;
	*Pointer<Int>(primitive + OFFSET(Primitive, yMax)) = yMax;

	// Sort by minimum y
	if(triangle)
	{
	Float y0 = *Pointer<Float>(v0 + OFFSET(Vertex, y));
	Float y1 = *Pointer<Float>(v1 + OFFSET(Vertex, y));
	Float y2 = *Pointer<Float>(v2 + OFFSET(Vertex, y));

	Float yMin = Min(Min(y0, y1), y2);

	conditionalRotate1(yMin == y1, v0, v1, v2);
	conditionalRotate2(yMin == y2, v0, v1, v2);
	}

	// Sort by maximum w
	if(triangle)
	{
	Float w0 = *Pointer<Float>(v0 + OFFSET(Vertex, w));
	Float w1 = *Pointer<Float>(v1 + OFFSET(Vertex, w));
	Float w2 = *Pointer<Float>(v2 + OFFSET(Vertex, w));

	Float wMax = Max(Max(w0, w1), w2);

	conditionalRotate1(wMax == w1, v0, v1, v2);
	conditionalRotate2(wMax == w2, v0, v1, v2);
	}

	Float w0 = *Pointer<Float>(v0 + OFFSET(Vertex, w));
	Float w1 = *Pointer<Float>(v1 + OFFSET(Vertex, w));
	Float w2 = *Pointer<Float>(v2 + OFFSET(Vertex, w));

	Float4 w012;

	w012.x = w0;
	w012.y = w1;
	w012.z = w2;
	w012.w = 1;

	Float rhw0 = *Pointer<Float>(v0 + OFFSET(Vertex, projected.w));

	Int X0 = *Pointer<Int>(v0 + OFFSET(Vertex, projected.x));
	Int X1 = *Pointer<Int>(v1 + OFFSET(Vertex, projected.x));
	Int X2 = *Pointer<Int>(v2 + OFFSET(Vertex, projected.x));

	Int Y0 = *Pointer<Int>(v0 + OFFSET(Vertex, projected.y));
	Int Y1 = *Pointer<Int>(v1 + OFFSET(Vertex, projected.y));
	Int Y2 = *Pointer<Int>(v2 + OFFSET(Vertex, projected.y));

	if(point)
	{
	Pointer<Float>(primitive + OFFSET(Primitive, pointCoordX)) = Float(1.0f / subPixF) Float(X0);
	Pointer<Float>(primitive + OFFSET(Primitive, pointCoordY)) = Float(1.0f / subPixF) Float(Y0);
	}

	if(line)
	{
	X2 = X1 + Y1 - Y0;
	Y2 = Y1 + X0 - X1;
	}

	Float dx = Float(X0) * (1.0f / subPixF);
	Float dy = Float(Y0) * (1.0f / subPixF);

	X1 -= X0;
	Y1 -= Y0;

	X2 -= X0;
	Y2 -= Y0;

	Float x1 = w1 * (1.0f / subPixF) * Float(X1);
	Float y1 = w1 * (1.0f / subPixF) * Float(Y1);

	Float x2 = w2 * (1.0f / subPixF) * Float(X2);
	Float y2 = w2 * (1.0f / subPixF) * Float(Y2);

	Float a = x1 * y2 - x2 * y1;

	Float4 xQuad = Float4(0, 1, 0, 1) - Float4(dx);
	Float4 yQuad = Float4(0, 0, 1, 1) - Float4(dy);

	*Pointer<Float4>(primitive + OFFSET(Primitive, xQuad), 16) = xQuad;
	*Pointer<Float4>(primitive + OFFSET(Primitive, yQuad), 16) = yQuad;

	Float4 M[3];

	M[0] = Float4(0, 0, 0, 0);
	M[1] = Float4(0, 0, 0, 0);
	M[2] = Float4(0, 0, 0, 0);

	M[0].z = rhw0;

	If(a != 0.0f)
	{
	Float A = 1.0f / a;
	Float D = A * rhw0;

	M[0].x = (y1 * w2 - y2 * w1) * D;
	M[0].y = (x2 * w1 - x1 * w2) * D;
	// M[0].z = rhw0;
	// M[0].w = 0;

	M[1].x = y2 * A;
	M[1].y = -x2 * A;
	// M[1].z = 0;
	// M[1].w = 0;

	M[2].x = -y1 * A;
	M[2].y = x1 * A;
	// M[2].z = 0;
	// M[2].w = 0;
	}

	if(state.interpolateW)
	{
	Float4 ABC = M[0] + M[1] + M[2];

	Float4 A = ABC.x;
	Float4 B = ABC.y;
	Float4 C = ABC.z;

	*Pointer<Float4>(primitive + OFFSET(Primitive, w.A), 16) = A;
	*Pointer<Float4>(primitive + OFFSET(Primitive, w.B), 16) = B;
	*Pointer<Float4>(primitive + OFFSET(Primitive, w.C), 16) = C;
	}

	if(state.interpolateZ)
	{
	Float z0 = *Pointer<Float>(v0 + OFFSET(Vertex, projected.z));
	Float z1 = *Pointer<Float>(v1 + OFFSET(Vertex, projected.z));
	Float z2 = *Pointer<Float>(v2 + OFFSET(Vertex, projected.z));

	z1 -= z0;
	z2 -= z0;

	Float A;
	Float B;
	Float C;

	if(!point)
	{
	Float x1 = Float(X1) * (1.0f / subPixF);
	Float y1 = Float(Y1) * (1.0f / subPixF);
	Float x2 = Float(X2) * (1.0f / subPixF);
	Float y2 = Float(Y2) * (1.0f / subPixF);

	Float D = Pointer<Float>(data + OFFSET(DrawData, depthRange)) / (x1 y2 - x2 * y1);

	A = (y2 * z1 - y1 * z2) * D;
	B = (x1 * z2 - x2 * z1) * D;
	}
	else
	{
	A = 0.0f;
	B = 0.0f;
	}

	C = z0 * Pointer<Float>(data + OFFSET(DrawData, depthRange)) + Pointer<Float>(data + OFFSET(DrawData, depthNear));

	*Pointer<Float4>(primitive + OFFSET(Primitive, z.A), 16) = Float4(A);
	*Pointer<Float4>(primitive + OFFSET(Primitive, z.B), 16) = Float4(B);
	*Pointer<Float4>(primitive + OFFSET(Primitive, z.C), 16) = Float4(C);

	Float bias = 0.0f;

	if(state.applyConstantDepthBias)
	{
	Float r; // Minimum resolvable difference

	if(state.fixedPointDepthBuffer)
	{
	// TODO(b/139341727): Pre-multiply the constant depth bias factor by the minimum
	// resolvable difference.

	// TODO(b/139341727): When there's a fixed-point depth buffer and no depth bias clamp,
	// the constant depth bias factor could be added to 'depthNear', eliminating the per-
	// polygon addition.

	r = *Pointer<Float>(data + OFFSET(DrawData, minimumResolvableDepthDifference));
	}
	else // Floating-point depth buffer
	{
	// "For floating-point depth buffers, there is no single minimum resolvable difference.
	// In this case, the minimum resolvable difference for a given polygon is dependent on
	// the maximum exponent, e, in the range of z values spanned by the primitive. If n is
	// the number of bits in the floating-point mantissa, the minimum resolvable difference,
	// r, for the given primitive is defined as r = 2^(e-n)."

	Float Z0 = C;
	Float Z1 = z1 * Pointer<Float>(data + OFFSET(DrawData, depthRange)) + Pointer<Float>(data + OFFSET(DrawData, depthNear));
	Float Z2 = z2 * Pointer<Float>(data + OFFSET(DrawData, depthRange)) + Pointer<Float>(data + OFFSET(DrawData, depthNear));

	Int e0 = As<Int>(Z0) & 0x7F800000;
	Int e1 = As<Int>(Z1) & 0x7F800000;
	Int e2 = As<Int>(Z2) & 0x7F800000;

	Int e = Max(Max(e0, e1), e2);

	r = As<Float>(e) * Float(1.0f / (1 << 23));
	}

	bias = r * *Pointer<Float>(data + OFFSET(DrawData, constantDepthBias));
	}

	if(state.applySlopeDepthBias)
	{
	Float m = Max(Abs(A), Abs(B));

	bias += m * *Pointer<Float>(data + OFFSET(DrawData, slopeDepthBias)); // TODO(b/155302798): Optimize 0 += x;
	}

	if(state.applyConstantDepthBias \|\| state.applySlopeDepthBias)
	{
	if(state.applyDepthBiasClamp)
	{
	Float clamp = *Pointer<Float>(data + OFFSET(DrawData, depthBiasClamp));

	bias = IfThenElse(clamp > 0.0f, Min(bias, clamp), Max(bias, clamp));
	}

	*Pointer<Float4>(primitive + OFFSET(Primitive, zBias), 16) = Float4(bias);
	}
	}

	int packedInterpolant = 0;
	for(int interfaceInterpolant = 0; interfaceInterpolant < MAX_INTERFACE_COMPONENTS; interfaceInterpolant++)
	{
	if(state.gradient[interfaceInterpolant].Type != SpirvShader::ATTRIBTYPE_UNUSED)
	{
	setupGradient(primitive, tri, w012, M, v0, v1, v2,
	OFFSET(Vertex, v[interfaceInterpolant]),
	OFFSET(Primitive, V[packedInterpolant]),
	state.gradient[interfaceInterpolant].Flat,
	!state.gradient[interfaceInterpolant].NoPerspective);
	packedInterpolant++;
	}
	}

	for(unsigned int i = 0; i < state.numClipDistances; i++)
	{
	setupGradient(primitive, tri, w012, M, v0, v1, v2,
	OFFSET(Vertex, clipDistance[i]),
	OFFSET(Primitive, clipDistance[i]),
	false, true);
	}

	for(unsigned int i = 0; i < state.numCullDistances; i++)
	{
	setupGradient(primitive, tri, w012, M, v0, v1, v2,
	OFFSET(Vertex, cullDistance[i]),
	OFFSET(Primitive, cullDistance[i]),
	false, true);
	}

	Return(1);
	}

	routine = function("SetupRoutine");
	}

	void SetupRoutine::setupGradient(Pointer<Byte> &primitive, Pointer<Byte> &triangle, Float4 &w012, Float4 (&m)[3], Pointer<Byte> &v0, Pointer<Byte> &v1, Pointer<Byte> &v2, int attribute, int planeEquation, bool flat, bool perspective)
	{
	if(!flat)
	{
	Float4 i;
	i.x = *Pointer<Float>(v0 + attribute);
	i.y = *Pointer<Float>(v1 + attribute);
	i.z = *Pointer<Float>(v2 + attribute);
	i.w = 0;

	if(!perspective)
	{
	i *= w012;
	}

	Float4 A = i.xxxx * m[0];
	Float4 B = i.yyyy * m[1];
	Float4 C = i.zzzz * m[2];

	C = A + B + C;

	A = C.xxxx;
	B = C.yyyy;
	C = C.zzzz;

	*Pointer<Float4>(primitive + planeEquation + 0, 16) = A;
	*Pointer<Float4>(primitive + planeEquation + 16, 16) = B;
	*Pointer<Float4>(primitive + planeEquation + 32, 16) = C;
	}
	else
	{
	int leadingVertex = OFFSET(Triangle, v0);
	Float C = *Pointer<Float>(triangle + leadingVertex + attribute);

	*Pointer<Float4>(primitive + planeEquation + 0, 16) = Float4(0, 0, 0, 0);
	*Pointer<Float4>(primitive + planeEquation + 16, 16) = Float4(0, 0, 0, 0);
	*Pointer<Float4>(primitive + planeEquation + 32, 16) = Float4(C);
	}
	}

	void SetupRoutine::edge(Pointer<Byte> &primitive, Pointer<Byte> &data, const Int &Xa, const Int &Ya, const Int &Xb, const Int &Yb, Int &q)
	{
	If(Ya != Yb)
	{
	Bool swap = Yb < Ya;

	Int X1 = IfThenElse(swap, Xb, Xa);
	Int X2 = IfThenElse(swap, Xa, Xb);
	Int Y1 = IfThenElse(swap, Yb, Ya);
	Int Y2 = IfThenElse(swap, Ya, Yb);

	constexpr int subPixB = vk::SUBPIXEL_PRECISION_BITS;
	constexpr int subPixM = vk::SUBPIXEL_PRECISION_MASK;

	Int y1 = Max((Y1 + subPixM) >> subPixB, *Pointer<Int>(data + OFFSET(DrawData, scissorY0)));
	Int y2 = Min((Y2 + subPixM) >> subPixB, *Pointer<Int>(data + OFFSET(DrawData, scissorY1)));

	If(y1 < y2)
	{
	Int xMin = *Pointer<Int>(data + OFFSET(DrawData, scissorX0));
	Int xMax = *Pointer<Int>(data + OFFSET(DrawData, scissorX1));

	Pointer<Byte> leftEdge = primitive + q * sizeof(Primitive) + OFFSET(Primitive, outline->left);
	Pointer<Byte> rightEdge = primitive + q * sizeof(Primitive) + OFFSET(Primitive, outline->right);
	Pointer<Byte> edge = IfThenElse(swap, rightEdge, leftEdge);

	// Deltas
	Int DX12 = X2 - X1;
	Int DY12 = Y2 - Y1;

	Int FDX12 = DX12 << subPixB;
	Int FDY12 = DY12 << subPixB;

	Int X = DX12 * ((y1 << subPixB) - Y1) + (X1 & subPixM) * DY12;
	Int x = (X1 >> subPixB) + X / FDY12; // Edge
	Int d = X % FDY12; // Error-term
	Int ceil = -d >> 31; // Ceiling division: remainder <= 0
	x -= ceil;
	d -= ceil & FDY12;

	Int Q = FDX12 / FDY12; // Edge-step
	Int R = FDX12 % FDY12; // Error-step
	Int floor = R >> 31; // Flooring division: remainder >= 0
	Q += floor;
	R += floor & FDY12;

	Int D = FDY12; // Error-overflow
	Int y = y1;

	Do
	{
	Pointer<Short>(edge + y sizeof(Primitive::Span)) = Short(Clamp(x, xMin, xMax));

	x += Q;
	d += R;

	Int overflow = -d >> 31;

	d -= D & overflow;
	x -= overflow;

	y++;
	}
	Until(y >= y2);
	}
	}
	}

	void SetupRoutine::conditionalRotate1(Bool condition, Pointer<Byte> &v0, Pointer<Byte> &v1, Pointer<Byte> &v2)
	{
	#if 0 // Rely on LLVM optimization
	If(condition)
	{
	Pointer<Byte> vX;

	vX = v0;
	v0 = v1;
	v1 = v2;
	v2 = vX;
	}
	#else
	Pointer<Byte> vX = v0;
	v0 = IfThenElse(condition, v1, v0);
	v1 = IfThenElse(condition, v2, v1);
	v2 = IfThenElse(condition, vX, v2);
	#endif
	}

	void SetupRoutine::conditionalRotate2(Bool condition, Pointer<Byte> &v0, Pointer<Byte> &v1, Pointer<Byte> &v2)
	{
	#if 0 // Rely on LLVM optimization
	If(condition)
	{
	Pointer<Byte> vX;

	vX = v2;
	v2 = v1;
	v1 = v0;
	v0 = vX;
	}
	#else
	Pointer<Byte> vX = v2;
	v2 = IfThenElse(condition, v1, v2);
	v1 = IfThenElse(condition, v0, v1);
	v0 = IfThenElse(condition, vX, v0);
	#endif
	}

	SetupFunction::RoutineType SetupRoutine::getRoutine()
	{
	return routine;
	}

	} // namespace sw