bullet3/examples/TinyRenderer/TinyRenderer.cpp

#include "TinyRenderer.h"

#include <vector>
#include <limits>
#include <iostream>
#include "tgaimage.h"
#include "model.h"
#include "geometry.h"
#include "our_gl.h"
#include "../Utils/b3ResourcePath.h"
#include "Bullet3Common/b3MinMax.h"
#include "../OpenGLWindow/ShapeData.h"
#include "LinearMath/btAlignedObjectArray.h"
#include "LinearMath/btVector3.h"
#include "Bullet3Common/b3Logging.h"

struct DepthShader : public IShader {
    
    Model* m_model;
    Matrix& m_modelMat;
    Matrix m_invModelMat;
    
    Matrix& m_projectionMat;
    Vec3f m_localScaling;
    Matrix& m_lightModelView;
    float m_lightDistance;
    
    mat<2,3,float> varying_uv;  // triangle uv coordinates, written by the vertex shader, read by the fragment shader
    mat<4,3,float> varying_tri; // triangle coordinates (clip coordinates), written by VS, read by FS
    
    mat<3,3,float> varying_nrm; // normal per vertex to be interpolated by FS
    
    DepthShader(Model* model, Matrix& lightModelView, Matrix& projectionMat, Matrix& modelMat, Vec3f localScaling, float lightDistance)
    :m_model(model),
    m_modelMat(modelMat),
	m_projectionMat(projectionMat),
	m_localScaling(localScaling),
	m_lightModelView(lightModelView),
	m_lightDistance(lightDistance)
    {
	m_nearPlane = m_projectionMat.col(3)[2]/(m_projectionMat.col(2)[2]-1);
	m_farPlane = m_projectionMat.col(3)[2]/(m_projectionMat.col(2)[2]+1);

        m_invModelMat = m_modelMat.invert_transpose();
    }
    virtual Vec4f vertex(int iface, int nthvert) {
        Vec2f uv = m_model->uv(iface, nthvert);
        varying_uv.set_col(nthvert, uv);
        varying_nrm.set_col(nthvert, proj<3>(m_invModelMat*embed<4>(m_model->normal(iface, nthvert), 0.f)));
        Vec3f unScaledVert = m_model->vert(iface, nthvert);
        Vec3f scaledVert=Vec3f(unScaledVert[0]*m_localScaling[0],
                               unScaledVert[1]*m_localScaling[1],
                               unScaledVert[2]*m_localScaling[2]);
        Vec4f gl_Vertex = m_projectionMat*m_lightModelView*embed<4>(scaledVert);
        varying_tri.set_col(nthvert, gl_Vertex);
        return gl_Vertex;
    }
    
    virtual bool fragment(Vec3f bar, TGAColor &color) {
        Vec4f p = varying_tri*bar;
        color = TGAColor(255, 255, 255)*(p[2]/m_lightDistance);
        return false;
    }
};

struct Shader : public IShader {
    
    Model* m_model;
    Vec3f m_light_dir_local;
    Vec3f m_light_color;
    Matrix& m_modelMat;
    Matrix m_invModelMat;
    Matrix& m_modelView1;
    Matrix& m_projectionMat;
    Vec3f m_localScaling;
    Matrix& m_lightModelView;
    Vec4f m_colorRGBA;
    Matrix& m_viewportMat;
	Matrix m_projectionModelViewMat;
	Matrix m_projectionLightViewMat;
    float m_ambient_coefficient;
    float m_diffuse_coefficient;
    float m_specular_coefficient;
    
    b3AlignedObjectArray<float>* m_shadowBuffer;
    
    int m_width;
    int m_height;
    
    int m_index;
    
    mat<2,3,float> varying_uv;  // triangle uv coordinates, written by the vertex shader, read by the fragment shader
    mat<4,3,float> varying_tri; // triangle coordinates (clip coordinates), written by VS, read by FS
    mat<4,3,float> varying_tri_light_view;
    mat<3,3,float> varying_nrm; // normal per vertex to be interpolated by FS
	mat<4,3,float> world_tri; // model triangle coordinates in the world space used for backface culling, written by VS
   

    Shader(Model* model, Vec3f light_dir_local, Vec3f light_color, Matrix& modelView, Matrix& lightModelView, Matrix& projectionMat, Matrix& modelMat, Matrix& viewportMat, Vec3f localScaling, const Vec4f& colorRGBA, int width, int height, b3AlignedObjectArray<float>* shadowBuffer, float ambient_coefficient=0.6, float diffuse_coefficient=0.35, float specular_coefficient=0.05)
    :m_model(model),
    m_light_dir_local(light_dir_local),
    m_light_color(light_color),
	m_modelMat(modelMat),
	m_modelView1(modelView),
	m_projectionMat(projectionMat),
	m_localScaling(localScaling),
	m_lightModelView(lightModelView),
	m_colorRGBA(colorRGBA),
	m_viewportMat(viewportMat),
	m_ambient_coefficient(ambient_coefficient),
	m_diffuse_coefficient(diffuse_coefficient),
	m_specular_coefficient(specular_coefficient),

	m_shadowBuffer(shadowBuffer),
	m_width(width),
    m_height(height)
   
    {
		m_nearPlane = m_projectionMat.col(3)[2]/(m_projectionMat.col(2)[2]-1);
		m_farPlane = m_projectionMat.col(3)[2]/(m_projectionMat.col(2)[2]+1);
		//printf("near=%f, far=%f\n", m_nearPlane, m_farPlane);
        m_invModelMat = m_modelMat.invert_transpose();
		m_projectionModelViewMat = m_projectionMat*m_modelView1;
		m_projectionLightViewMat = m_projectionMat*m_lightModelView;
    }
    virtual Vec4f vertex(int iface, int nthvert) {
		//B3_PROFILE("vertex");
        Vec2f uv = m_model->uv(iface, nthvert);
        varying_uv.set_col(nthvert, uv);
        varying_nrm.set_col(nthvert, proj<3>(m_invModelMat*embed<4>(m_model->normal(iface, nthvert), 0.f)));
        Vec3f unScaledVert = m_model->vert(iface, nthvert);
        Vec3f scaledVert=Vec3f(unScaledVert[0]*m_localScaling[0],
                               unScaledVert[1]*m_localScaling[1],
                               unScaledVert[2]*m_localScaling[2]);
        Vec4f gl_Vertex = m_projectionModelViewMat*embed<4>(scaledVert);
        varying_tri.set_col(nthvert, gl_Vertex);
		Vec4f world_Vertex = m_modelMat*embed<4>(scaledVert);
		world_tri.set_col(nthvert, world_Vertex);
        Vec4f gl_VertexLightView = m_projectionLightViewMat*embed<4>(scaledVert);
        varying_tri_light_view.set_col(nthvert, gl_VertexLightView);
        return gl_Vertex;
    }
    
    virtual bool fragment(Vec3f bar, TGAColor &color) {
		//B3_PROFILE("fragment");
        Vec4f p = m_viewportMat*(varying_tri_light_view*bar);
        float depth = p[2];
        p = p/p[3];
        
		float index_x = b3Max(float(0.0), b3Min(float(m_width-1), p[0]));
		float index_y = b3Max(float(0.0), b3Min(float(m_height-1), p[1]));
		int idx = int(index_x) + int(index_y)*m_width; // index in the shadowbuffer array
        float shadow = 0.8+0.2*(m_shadowBuffer->at(idx)<-depth+0.05); // magic coeff to avoid z-fighting
        
        Vec3f bn = (varying_nrm*bar).normalize();
        Vec2f uv = varying_uv*bar;
        
        Vec3f reflection_direction = (bn * (bn * m_light_dir_local * 2.f) - m_light_dir_local).normalize();
        float specular = pow(b3Max(reflection_direction.z, 0.f), m_model->specular(uv));
        float diffuse = b3Max(0.f, bn * m_light_dir_local);
        
        color = m_model->diffuse(uv);
        color[0] *= m_colorRGBA[0];
        color[1] *= m_colorRGBA[1];
        color[2] *= m_colorRGBA[2];
        color[3] *= m_colorRGBA[3];
        
        for (int i = 0; i < 3; ++i)
        {
            color[i] = b3Min(int(m_ambient_coefficient*color[i] + shadow*(m_diffuse_coefficient*diffuse+m_specular_coefficient*specular)*color[i]*m_light_color[i]), 255);
        }
        
        return false;

    }
};

TinyRenderObjectData::TinyRenderObjectData(TGAImage& rgbColorBuffer,b3AlignedObjectArray<float>&depthBuffer,b3AlignedObjectArray<float>* shadowBuffer)
:
m_model(0),
m_rgbColorBuffer(rgbColorBuffer),
m_depthBuffer(depthBuffer),
m_shadowBuffer(shadowBuffer),
m_segmentationMaskBufferPtr(0),
m_userData(0),
m_userIndex(-1),
m_objectIndex(-1)
{
    Vec3f       eye(1,1,3);
    Vec3f    center(0,0,0);
    Vec3f        up(0,0,1);
    m_lightDirWorld.setValue(0,0,0);
    m_lightColor.setValue(1, 1, 1);
    m_localScaling.setValue(1,1,1);
    m_modelMatrix = Matrix::identity();
    m_lightAmbientCoeff = 0.6;
    m_lightDiffuseCoeff = 0.35;
    m_lightSpecularCoeff = 0.05;
    
}

TinyRenderObjectData::TinyRenderObjectData(TGAImage& rgbColorBuffer,b3AlignedObjectArray<float>&depthBuffer, b3AlignedObjectArray<float>* shadowBuffer, b3AlignedObjectArray<int>* segmentationMaskBuffer, int objectIndex)
:m_model(0),
m_rgbColorBuffer(rgbColorBuffer),
m_depthBuffer(depthBuffer),
m_shadowBuffer(shadowBuffer),
m_segmentationMaskBufferPtr(segmentationMaskBuffer),
m_userData(0),
m_userIndex(-1),
m_objectIndex(objectIndex)
{
    Vec3f       eye(1,1,3);
    Vec3f    center(0,0,0);
    Vec3f        up(0,0,1);
    m_lightDirWorld.setValue(0,0,0);
    m_lightColor.setValue(1, 1, 1);
    m_localScaling.setValue(1,1,1);
    m_modelMatrix = Matrix::identity();
    m_lightAmbientCoeff = 0.6;
    m_lightDiffuseCoeff = 0.35;
    m_lightSpecularCoeff = 0.05;
    
}

TinyRenderObjectData::TinyRenderObjectData(TGAImage& rgbColorBuffer,b3AlignedObjectArray<float>&depthBuffer)
:m_model(0),
m_rgbColorBuffer(rgbColorBuffer),
m_depthBuffer(depthBuffer),
m_segmentationMaskBufferPtr(0),
m_userData(0),
m_userIndex(-1),
m_objectIndex(-1)
{
    Vec3f       eye(1,1,3);
    Vec3f    center(0,0,0);
    Vec3f        up(0,0,1);
    m_lightDirWorld.setValue(0,0,0);
	m_lightColor.setValue(1, 1, 1);
	m_localScaling.setValue(1,1,1);
    m_modelMatrix = Matrix::identity();
    m_lightAmbientCoeff = 0.6;
    m_lightDiffuseCoeff = 0.35;
    m_lightSpecularCoeff = 0.05;
 
}

TinyRenderObjectData::TinyRenderObjectData(TGAImage& rgbColorBuffer,b3AlignedObjectArray<float>&depthBuffer, b3AlignedObjectArray<int>* segmentationMaskBuffer, int objectIndex)
:m_model(0),
m_rgbColorBuffer(rgbColorBuffer),
m_depthBuffer(depthBuffer),
m_segmentationMaskBufferPtr(segmentationMaskBuffer),
m_userData(0),
m_userIndex(-1),
m_objectIndex(objectIndex)
{
    Vec3f       eye(1,1,3);
    Vec3f    center(0,0,0);
    Vec3f        up(0,0,1);
    m_lightDirWorld.setValue(0,0,0);
	m_lightColor.setValue(1, 1, 1);
	m_localScaling.setValue(1,1,1);
    m_modelMatrix = Matrix::identity();
    m_lightAmbientCoeff = 0.6;
    m_lightDiffuseCoeff = 0.35;
    m_lightSpecularCoeff = 0.05;
 
}

void TinyRenderObjectData::loadModel(const char* fileName)
{
 //todo(erwincoumans) move the file loading out of here
   char relativeFileName[1024];
    if (!b3ResourcePath::findResourcePath(fileName, relativeFileName, 1024))
    {
        printf("Cannot find file %s\n", fileName);
    } else
    {
        m_model = new Model(relativeFileName);
    }   
}


void TinyRenderObjectData::registerMeshShape(const float* vertices, int numVertices,const int* indices, int numIndices, const float rgbaColor[4],
	unsigned char* textureImage, int textureWidth, int textureHeight)
{
	if (0==m_model)
    {
		{
			B3_PROFILE("setColorRGBA");

			m_model = new Model();
			m_model->setColorRGBA(rgbaColor);
		}
		if (textureImage)
		{
			{
				B3_PROFILE("setDiffuseTextureFromData");
				m_model->setDiffuseTextureFromData(textureImage, textureWidth, textureHeight);
			}
		} else
		{
			/*char relativeFileName[1024];
			if (b3ResourcePath::findResourcePath("floor_diffuse.tga", relativeFileName, 1024))
			{
				m_model->loadDiffuseTexture(relativeFileName);
			}
             */
		}
		{
			B3_PROFILE("reserveMemory");
			m_model->reserveMemory(numVertices, numIndices);
		}
		{
			B3_PROFILE("addVertex");
			for (int i = 0; i < numVertices; i++)
			{
				m_model->addVertex(vertices[i * 9],
					vertices[i * 9 + 1],
					vertices[i * 9 + 2],
					vertices[i * 9 + 4],
					vertices[i * 9 + 5],
					vertices[i * 9 + 6],
					vertices[i * 9 + 7],
					vertices[i * 9 + 8]);
			}
		}
		{
			B3_PROFILE("addTriangle");
			for (int i = 0; i < numIndices; i += 3)
			{
				m_model->addTriangle(indices[i], indices[i], indices[i],
					indices[i + 1], indices[i + 1], indices[i + 1],
					indices[i + 2], indices[i + 2], indices[i + 2]);
			}
		}
    }
}

void TinyRenderObjectData::registerMesh2(btAlignedObjectArray<btVector3>& vertices, btAlignedObjectArray<btVector3>& normals,btAlignedObjectArray<int>& indices)
{
	if (0==m_model)
    {
		int numVertices = vertices.size();
		int numIndices = indices.size();

        m_model = new Model();
		char relativeFileName[1024];
		if (b3ResourcePath::findResourcePath("floor_diffuse.tga", relativeFileName, 1024))
		{
			m_model->loadDiffuseTexture(relativeFileName);
		}
		
        for (int i=0;i<numVertices;i++)
        {
            m_model->addVertex(vertices[i].x(),
                         vertices[i].y(),
                         vertices[i].z(),
                         normals[i].x(),
                         normals[i].y(),
                         normals[i].z(),
                         0.5,0.5);
        }
        for (int i=0;i<numIndices;i+=3)
        {
            m_model->addTriangle(indices[i],indices[i],indices[i],
                                 indices[i+1],indices[i+1],indices[i+1],
                                 indices[i+2],indices[i+2],indices[i+2]);
        }
    }
}

void TinyRenderObjectData::createCube(float halfExtentsX,float halfExtentsY,float halfExtentsZ)
{
    m_model = new Model();
    
    char relativeFileName[1024];
    if (b3ResourcePath::findResourcePath("floor_diffuse.tga", relativeFileName, 1024))
    {
        m_model->loadDiffuseTexture(relativeFileName);
    }
    

	int strideInBytes = 9*sizeof(float);
	int numVertices = sizeof(cube_vertices_textured)/strideInBytes;
	int numIndices = sizeof(cube_indices)/sizeof(int);

	for (int i=0;i<numVertices;i++)
	{
		m_model->addVertex(halfExtentsX*cube_vertices_textured[i*9],
                     halfExtentsY*cube_vertices_textured[i*9+1],
                     halfExtentsY*cube_vertices_textured[i*9+2],
                     cube_vertices_textured[i*9+4],
                     cube_vertices_textured[i*9+5],
                     cube_vertices_textured[i*9+6],
                     cube_vertices_textured[i*9+7],
                     cube_vertices_textured[i*9+8]);
	}
	for (int i=0;i<numIndices;i+=3)
    {
        m_model->addTriangle(cube_indices[i],cube_indices[i],cube_indices[i],
                             cube_indices[i+1],cube_indices[i+1],cube_indices[i+1],
                             cube_indices[i+2],cube_indices[i+2],cube_indices[i+2]);
    }
	
}

TinyRenderObjectData::~TinyRenderObjectData()
{
    delete m_model;
}

static bool equals(const Vec4f& vA, const Vec4f& vB)
{
	return false;
}

static void clipEdge(const mat<4,3,float>& triangleIn, int vertexIndexA, int vertexIndexB, b3AlignedObjectArray<Vec4f>& vertices)
{
	Vec4f v0New = triangleIn.col(vertexIndexA);
	Vec4f v1New = triangleIn.col(vertexIndexB);

	bool v0Inside = v0New[3] > 0.f && v0New[2] > -v0New[3];
	bool v1Inside= v1New[3] > 0.f && v1New[2] > -v1New[3];

	if (v0Inside && v1Inside)
	{

	} else if (v0Inside || v1Inside)
	{
		float d0 = v0New[2]+v0New[3];
		float d1 = v1New[2]+v1New[3];
		float factor = 1.0 / (d1-d0);
		Vec4f newVertex =(v0New*d1-v1New*d0)*factor;
		if (v0Inside)
		{
			v1New = newVertex;
		} else
		{
			v0New = newVertex;
		}
	} else
	{
		return;
	}

	if (vertices.size()==0 || !(equals(vertices[vertices.size()-1],v0New)))
	{
		vertices.push_back(v0New);
	}

	vertices.push_back(v1New);
}




static bool clipTriangleAgainstNearplane(const mat<4,3,float>& triangleIn, b3AlignedObjectArray<mat<4,3,float> >& clippedTrianglesOut)
{


	//discard triangle if all vertices are behind near-plane
	if (triangleIn[3][0]<0 && triangleIn[3][1] <0 && triangleIn[3][2] <0)
	{
		return true;
	}

	//accept triangle if all vertices are in front of the near-plane
	if (triangleIn[3][0]>=0 && triangleIn[3][1] >=0 && triangleIn[3][2] >=0)
	{
		clippedTrianglesOut.push_back(triangleIn);
		return false;
	}

	Vec4f vtxCache[5];

	b3AlignedObjectArray<Vec4f> vertices;
	vertices.initializeFromBuffer(vtxCache,0,5);
	clipEdge(triangleIn,0,1,vertices);
	clipEdge(triangleIn,1,2,vertices);
	clipEdge(triangleIn,2,0,vertices);

	if (vertices.size()<3)
		return true;
	
	if (equals(vertices[0],vertices[vertices.size()-1]))
	{
		vertices.pop_back();
	}

	//create a fan of triangles
	for (int i=1;i<vertices.size()-1;i++)
	{
		mat<4,3,float>& vtx = clippedTrianglesOut.expand();
		vtx.set_col(0,vertices[0]);
		vtx.set_col(1,vertices[i]);
		vtx.set_col(2,vertices[i+1]);
	}
	return true;
}

void TinyRenderer::renderObject(TinyRenderObjectData& renderData)
{
	B3_PROFILE("renderObject");
    int width = renderData.m_rgbColorBuffer.get_width();
    int height = renderData.m_rgbColorBuffer.get_height();
    
    Vec3f light_dir_local = Vec3f(renderData.m_lightDirWorld[0],renderData.m_lightDirWorld[1],renderData.m_lightDirWorld[2]);
    Vec3f light_color = Vec3f(renderData.m_lightColor[0],renderData.m_lightColor[1],renderData.m_lightColor[2]);
    float light_distance = renderData.m_lightDistance;
    Model* model = renderData.m_model;
    if (0==model)
        return;
	//discard invisible objects (zero alpha)
	if (model->getColorRGBA()[3]==0)
		return;

    renderData.m_viewportMatrix = viewport(0,0,width, height);
    
    b3AlignedObjectArray<float>& zbuffer = renderData.m_depthBuffer;
    b3AlignedObjectArray<float>* shadowBufferPtr = renderData.m_shadowBuffer;
    int* segmentationMaskBufferPtr = (renderData.m_segmentationMaskBufferPtr && renderData.m_segmentationMaskBufferPtr->size())?&renderData.m_segmentationMaskBufferPtr->at(0):0;
    
    TGAImage& frame = renderData.m_rgbColorBuffer;
    
    {
        // light target is set to be the origin, and the up direction is set to be vertical up.
        Matrix lightViewMatrix = lookat(light_dir_local*light_distance, Vec3f(0.0,0.0,0.0), Vec3f(0.0,0.0,1.0));
        Matrix lightModelViewMatrix = lightViewMatrix*renderData.m_modelMatrix;
        Matrix modelViewMatrix = renderData.m_viewMatrix*renderData.m_modelMatrix;
        Vec3f localScaling(renderData.m_localScaling[0],renderData.m_localScaling[1],renderData.m_localScaling[2]);
		Matrix viewMatrixInv = renderData.m_viewMatrix.invert();
		btVector3 P(viewMatrixInv[0][3], viewMatrixInv[1][3], viewMatrixInv[2][3]);
        
        Shader shader(model, light_dir_local, light_color, modelViewMatrix, lightModelViewMatrix, renderData.m_projectionMatrix,renderData.m_modelMatrix, renderData.m_viewportMatrix, localScaling, model->getColorRGBA(), width, height, shadowBufferPtr, renderData.m_lightAmbientCoeff, renderData.m_lightDiffuseCoeff, renderData.m_lightSpecularCoeff);
       
		{
		B3_PROFILE("face");

        for (int i=0; i<model->nfaces(); i++)
        {
            for (int j=0; j<3; j++) {
                shader.vertex(i, j);
            }
			
			// backface culling
			btVector3 v0(shader.world_tri.col(0)[0], shader.world_tri.col(0)[1], shader.world_tri.col(0)[2]);
			btVector3 v1(shader.world_tri.col(1)[0], shader.world_tri.col(1)[1], shader.world_tri.col(1)[2]);
			btVector3 v2(shader.world_tri.col(2)[0], shader.world_tri.col(2)[1], shader.world_tri.col(2)[2]);
			btVector3 N = (v1-v0).cross(v2-v0);
			if ((v0-P).dot(N) >= 0)
				continue;

			mat<4,3,float> stackTris[3];

			b3AlignedObjectArray< mat<4,3,float> > clippedTriangles;
			clippedTriangles.initializeFromBuffer(stackTris,0,3);

			bool hasClipped = clipTriangleAgainstNearplane(shader.varying_tri,clippedTriangles);

			if (hasClipped)
			{
				for (int t=0;t<clippedTriangles.size();t++)
				{
					triangleClipped(clippedTriangles[t], shader.varying_tri, shader, frame, &zbuffer[0], segmentationMaskBufferPtr, renderData.m_viewportMatrix, renderData.m_objectIndex);
				}
			}
			else
			{
				triangle(shader.varying_tri, shader, frame, &zbuffer[0], segmentationMaskBufferPtr, renderData.m_viewportMatrix, renderData.m_objectIndex);
			}
        }
		}
    }
    
}


void TinyRenderer::renderObjectDepth(TinyRenderObjectData& renderData)
{
    int width = renderData.m_rgbColorBuffer.get_width();
    int height = renderData.m_rgbColorBuffer.get_height();
    
    Vec3f light_dir_local = Vec3f(renderData.m_lightDirWorld[0],renderData.m_lightDirWorld[1],renderData.m_lightDirWorld[2]);
    float light_distance = renderData.m_lightDistance;
    Model* model = renderData.m_model;
    if (0==model)
        return;
    
    renderData.m_viewportMatrix = viewport(0,0,width, height);
    
    float* shadowBufferPtr = (renderData.m_shadowBuffer && renderData.m_shadowBuffer->size())?&renderData.m_shadowBuffer->at(0):0;
    int* segmentationMaskBufferPtr = 0;
    
    TGAImage depthFrame(width, height, TGAImage::RGB);
    
    {
        // light target is set to be the origin, and the up direction is set to be vertical up.
        Matrix lightViewMatrix = lookat(light_dir_local*light_distance, Vec3f(0.0,0.0,0.0), Vec3f(0.0,0.0,1.0));
        Matrix lightModelViewMatrix = lightViewMatrix*renderData.m_modelMatrix;
        Matrix lightViewProjectionMatrix = renderData.m_projectionMatrix;
        Vec3f localScaling(renderData.m_localScaling[0],renderData.m_localScaling[1],renderData.m_localScaling[2]);
        
        DepthShader shader(model, lightModelViewMatrix, lightViewProjectionMatrix,renderData.m_modelMatrix, localScaling, light_distance);
        for (int i=0; i<model->nfaces(); i++)
        {
            for (int j=0; j<3; j++) {
                shader.vertex(i, j);
            }


			mat<4,3,float> stackTris[3];

			b3AlignedObjectArray< mat<4,3,float> > clippedTriangles;
			clippedTriangles.initializeFromBuffer(stackTris,0,3);

			bool hasClipped = clipTriangleAgainstNearplane(shader.varying_tri,clippedTriangles);

			if (hasClipped)
			{
				for (int t=0;t<clippedTriangles.size();t++)
				{
					triangleClipped(clippedTriangles[t], shader.varying_tri, shader, depthFrame, shadowBufferPtr, segmentationMaskBufferPtr, renderData.m_viewportMatrix, renderData.m_objectIndex);
				}
			} else
			{
					triangle(shader.varying_tri, shader, depthFrame, shadowBufferPtr, segmentationMaskBufferPtr, renderData.m_viewportMatrix, renderData.m_objectIndex);
			}
        }
    }
    
}