source: GTP/branches/IllumWPdeliver2008dec/IlluminationWP/demos/Standalone/PathMap [DirectX]/TriangleMesh.cpp @ 3255

#include "dxstdafx.h"
#include "trianglemesh.h"
#include "Radion.hpp"

TriangleMesh::TriangleMesh(Material* material, unsigned short* indexBuffer, unsigned int nFaces,
                                                   FlexVertexArray& vertexBuffer, unsigned int nVertices)
{
        this->material = material;
        nMeshVertices = nVertices;
        nMeshPatches = nFaces;

        meshVertices = new Vector[nMeshVertices];
        normals = new Vector[nMeshVertices];
        texCoords = new Vector[nMeshVertices];
        for(int u=0; u < nMeshVertices; u++)
        {
                meshVertices[u] = vertexBuffer[u].pos();
                normals[u] = vertexBuffer[u].normal();
                texCoords[u] = vertexBuffer[u].tex0();
        }
        
        meshPatches = new Patch[nMeshPatches];

        int pup = 0;
        int p = 0;
        for(p = 0; p < nMeshPatches; p++)
        {
                meshPatches[p].vertexIndices[0] = indexBuffer[pup++];
                meshPatches[p].vertexIndices[1] = indexBuffer[pup++];
                meshPatches[p].vertexIndices[2] = indexBuffer[pup++];
        }
        //calculate normals
        for(p = 0; p < nMeshPatches; p++)
        {
                meshPatches[p].flatNormal = (
                        meshVertices[meshPatches[p].vertexIndices[0]] -
                        meshVertices[meshPatches[p].vertexIndices[1]]
                        )
                        &&
                        (
                        meshVertices[meshPatches[p].vertexIndices[0]] -
                        meshVertices[meshPatches[p].vertexIndices[2]]
                        );
                meshPatches[p].flatNormal.normalize();
                normals[meshPatches[p].vertexIndices[0]] += meshPatches[p].flatNormal;
                normals[meshPatches[p].vertexIndices[1]] += meshPatches[p].flatNormal;
                normals[meshPatches[p].vertexIndices[2]] += meshPatches[p].flatNormal;
                meshPatches[p].hyperPlaneShiftOffset = 
                        meshVertices[meshPatches[p].vertexIndices[0]] * 
                                                meshPatches[p].flatNormal;

                Vector A[3];
                A[0] = meshVertices[meshPatches[p].vertexIndices[0]];
                A[1] = meshVertices[meshPatches[p].vertexIndices[1]];
                A[2] = meshVertices[meshPatches[p].vertexIndices[2]];
                float           t4 = A[0][0]*A[1][1];
                float       t6 = A[0][0]*A[1][2];
                float       t8 = A[0][1]*A[1][0];
                float       t10 = A[0][2]*A[1][0];
                float       t12 = A[0][1]*A[2][0];
                float       t14 = A[0][2]*A[2][0];
                float       t17 = 1/(t4*A[2][2]-t6*A[2][1]-t8*A[2][2]+t10*A[2][1]+t12*A[1][2]-t14*A[1][1]);
        
//              if(_isnan (t17) )
//          AfxMessageBox("mtx inversion gbz");

                Vector* m = meshPatches[p].inverseVertexMatrix;
                
                m[0][0] = (A[1][1]*A[2][2]-A[1][2]*A[2][1])*t17;
                m[1][0] = -(A[0][1]*A[2][2]-A[0][2]*A[2][1])*t17;
                m[2][0] = -(-A[0][1]*A[1][2]+A[0][2]*A[1][1])*t17;
                m[0][1] = -(A[1][0]*A[2][2]-A[1][2]*A[2][0])*t17;
                m[1][1] = (A[0][0]*A[2][2]-t14)*t17;
                m[2][1] = -(t6-t10)*t17;
                m[0][2] = -(-A[1][0]*A[2][1]+A[1][1]*A[2][0])*t17;
                m[1][2] = -(A[0][0]*A[2][1]-t12)*t17;
                m[2][2] = (t4-t8)*t17;

                meshPatches[p].bbox.minPoint = meshVertices[meshPatches[p].vertexIndices[0]];
                meshPatches[p].bbox.minPoint <= meshVertices[meshPatches[p].vertexIndices[1]];
                meshPatches[p].bbox.minPoint <= meshVertices[meshPatches[p].vertexIndices[2]];

                meshPatches[p].bbox.maxPoint = meshVertices[meshPatches[p].vertexIndices[0]];
                meshPatches[p].bbox.maxPoint >= meshVertices[meshPatches[p].vertexIndices[1]];
                meshPatches[p].bbox.maxPoint >= meshVertices[meshPatches[p].vertexIndices[2]];
        }
        for(int n=0; n<nMeshVertices; n++)
        {
                normals[n].normalize();
        }
        Intersectable** objs = new Intersectable*[nMeshPatches];
        for(int t=0; t<nMeshPatches; t++)
                objs[t] = meshPatches + t;
        meshTree = new KDTree(objs, nMeshPatches);
        bbox = meshTree->getBoundingBox();
        delete objs;

        buildAreaTree();
}

TriangleMesh::TriangleMesh(std::istream& isc, Material** materialTable, int nMaterials)
{
        char keyword[100];
        isc >> keyword; //material
        isc >> keyword;
        for(int i=0; i < nMaterials; i++)
        {
                material = materialTable[i];
                if(strcmp(keyword, material->getName()) == 0) break;
        }
        isc >> keyword;
        isc >> nMeshVertices;
        meshVertices = new Vector[nMeshVertices];
        normals = new Vector[nMeshVertices];
        for(int v=0; v<nMeshVertices; v++)
        {
                float a, b, c;
                isc >> a >> b >> c;
//              meshVertices[v] = Vector(a + (0.1f * (float)rand() / RAND_MAX),
//                      b + (0.1f * (float)rand() / RAND_MAX),
//                      c + (0.1f * (float)rand() / RAND_MAX));
                meshVertices[v] = Vector(a , b, c);
                normals[v].clear();
        }
        bbox.minPoint = meshVertices[0];
        bbox.maxPoint = meshVertices[0];
        for(int w=1; w<nMeshVertices; w++)
        {
                bbox.minPoint <= meshVertices[w];
                bbox.maxPoint >= meshVertices[w];
        }
        isc >> keyword;
        isc >> nMeshPatches;
        meshPatches = new Patch[nMeshPatches];
        int p;
        for(p = 0; p < nMeshPatches; p++)
        {
                signed int ai, bi, ci;
                isc >> ai >> bi >> ci;
//              if(di < 0)
                {
                        meshPatches[p].vertexIndices[0] = ai;
                        meshPatches[p].vertexIndices[1] = bi;
                        meshPatches[p].vertexIndices[2] = ci;
                }
/*              else    //quad, tessellate
                {
                        meshPatches[p].vertexIndices[0] = ai;
                        meshPatches[p].vertexIndices[1] = bi;
                        meshPatches[p].vertexIndices[2] = ci;
                        p++;
                        meshPatches[p].vertexIndices[0] = ai;
                        meshPatches[p].vertexIndices[1] = ci;
                        meshPatches[p].vertexIndices[2] = di;
                        isc >> ai; //final -1
                }*/
        }
        //calculate normals
        for(p = 0; p < nMeshPatches; p++)
        {
                meshPatches[p].flatNormal = (
                        meshVertices[meshPatches[p].vertexIndices[0]] -
                        meshVertices[meshPatches[p].vertexIndices[1]]
                        )
                        &&
                        (
                        meshVertices[meshPatches[p].vertexIndices[0]] -
                        meshVertices[meshPatches[p].vertexIndices[2]]
                        );
                meshPatches[p].flatNormal.normalize();
                normals[meshPatches[p].vertexIndices[0]] += meshPatches[p].flatNormal;
                normals[meshPatches[p].vertexIndices[1]] += meshPatches[p].flatNormal;
                normals[meshPatches[p].vertexIndices[2]] += meshPatches[p].flatNormal;
                meshPatches[p].hyperPlaneShiftOffset = 
                        meshVertices[meshPatches[p].vertexIndices[0]] * 
                                                meshPatches[p].flatNormal;

                Vector A[3];
                A[0] = meshVertices[meshPatches[p].vertexIndices[0]];
                A[1] = meshVertices[meshPatches[p].vertexIndices[1]];
                A[2] = meshVertices[meshPatches[p].vertexIndices[2]];
                float           t4 = A[0][0]*A[1][1];
                float       t6 = A[0][0]*A[1][2];
                float       t8 = A[0][1]*A[1][0];
                float       t10 = A[0][2]*A[1][0];
                float       t12 = A[0][1]*A[2][0];
                float       t14 = A[0][2]*A[2][0];
                float       t17 = 1/(t4*A[2][2]-t6*A[2][1]-t8*A[2][2]+t10*A[2][1]+t12*A[1][2]-t14*A[1][1]);
        
//              if(_isnan (t17) )
//          AfxMessageBox("mtx inversion gbz");

                Vector* m = meshPatches[p].inverseVertexMatrix;
                
                m[0][0] = (A[1][1]*A[2][2]-A[1][2]*A[2][1])*t17;
                m[1][0] = -(A[0][1]*A[2][2]-A[0][2]*A[2][1])*t17;
                m[2][0] = -(-A[0][1]*A[1][2]+A[0][2]*A[1][1])*t17;
                m[0][1] = -(A[1][0]*A[2][2]-A[1][2]*A[2][0])*t17;
                m[1][1] = (A[0][0]*A[2][2]-t14)*t17;
                m[2][1] = -(t6-t10)*t17;
                m[0][2] = -(-A[1][0]*A[2][1]+A[1][1]*A[2][0])*t17;
                m[1][2] = -(A[0][0]*A[2][1]-t12)*t17;
                m[2][2] = (t4-t8)*t17;

                meshPatches[p].bbox.minPoint = meshVertices[meshPatches[p].vertexIndices[0]];
                meshPatches[p].bbox.minPoint <= meshVertices[meshPatches[p].vertexIndices[1]];
                meshPatches[p].bbox.minPoint <= meshVertices[meshPatches[p].vertexIndices[2]];

                meshPatches[p].bbox.maxPoint = meshVertices[meshPatches[p].vertexIndices[0]];
                meshPatches[p].bbox.maxPoint >= meshVertices[meshPatches[p].vertexIndices[1]];
                meshPatches[p].bbox.maxPoint >= meshVertices[meshPatches[p].vertexIndices[2]];
        }
        for(int n=0; n<nMeshVertices; n++)
        {
                normals[n].normalize();
        }
        Intersectable** objs = new Intersectable*[nMeshPatches];
        for(int t=0; t<nMeshPatches; t++)
                objs[t] = meshPatches + t;
        meshTree = new KDTree(objs, nMeshPatches);
        bbox = meshTree->getBoundingBox();
        delete objs;
}

void TriangleMesh::getTransformedBoundingBox(const Transformation& tf, BoundingBox& bb)
{
        Vector tfdvec;
        tf.transformPoint(meshVertices[0], tfdvec);
        bb.minPoint = tfdvec;
        bb.maxPoint = tfdvec;
        for(int w=1; w<nMeshVertices; w++)
        {
                tf.transformPoint(meshVertices[w], tfdvec);
                bb.minPoint <= tfdvec;
                bb.maxPoint >= tfdvec;
        }
        bb.minPoint.x -= 0.01;
        bb.minPoint.y -= 0.01;
        bb.minPoint.z -= 0.01;
        bb.maxPoint.x += 0.01;
        bb.maxPoint.y += 0.01;
        bb.maxPoint.z += 0.01;
}

bool TriangleMesh::Patch::intersectBackSide (const Ray& ray, float& depth, float rayMin, float rayMax)
{
        lastTestedRayId = ray.id;
        lastTestedRayResult.isIntersect = false;

        float cosa = flatNormal * ray.dir;
        if (cosa < 0.00001f)    // front facing triangle
                return false;

        float originDistOnNormal = -(flatNormal * ray.origin);
        depth = (hyperPlaneShiftOffset + originDistOnNormal) / cosa;
        if (depth < 0.01f)
                return false;

        Vector hitPoint = ray.origin;
        hitPoint.addScaled(depth, ray.dir);

        float baryA = hitPoint * inverseVertexMatrix[0];
        if(baryA < -0.0001f) return false;
        float baryB = hitPoint * inverseVertexMatrix[1];
        if(baryB < -0.0001f) return false;
        float baryC = hitPoint * inverseVertexMatrix[2];
        if(baryC < -0.0001f) return false;

        if(ray.isShadowRay)
        {
                //faster way to tell
                lastTestedRayResult.isIntersect = true;
                lastTestedRayResult.depth               = depth;
                return true;
        }

        lastTestedRayResult.normal.setScaled(baryA, meshNormals[vertexIndices[0]]);
        lastTestedRayResult.normal.addScaled(baryB, meshNormals[vertexIndices[1]]);
        lastTestedRayResult.normal.addScaled(baryC, meshNormals[vertexIndices[2]]);

        lastTestedRayResult.texUV.setScaled(baryA, meshTexCoords[vertexIndices[0]]);
        lastTestedRayResult.texUV.addScaled(baryB, meshTexCoords[vertexIndices[1]]);
        lastTestedRayResult.texUV.addScaled(baryC, meshTexCoords[vertexIndices[2]]);

        lastTestedRayResult.isIntersect = true;
        lastTestedRayResult.depth               = depth;
        lastTestedRayResult.point               = hitPoint;
        lastTestedRayResult.object              = this;
        return true;
}

bool TriangleMesh::Patch::intersect (const Ray& ray, float& depth, float rayMin, float rayMax)
{
        lastTestedRayId = ray.id;
        lastTestedRayResult.isIntersect = false;

        float cosa = flatNormal * ray.dir;
        if (cosa > -0.00001f)   // back facing triangle
                return false;

        float originDistOnNormal = -(flatNormal * ray.origin);
        depth = (hyperPlaneShiftOffset + originDistOnNormal) / cosa;
        if (depth < 0.0f)
                return false;

        Vector hitPoint = ray.origin;
        hitPoint.addScaled(depth, ray.dir);

        float baryA = hitPoint * inverseVertexMatrix[0];
        if(baryA < -0.1f) return false;
        float baryB = hitPoint * inverseVertexMatrix[1];
        if(baryB <  -0.1f) return false;
        float baryC = hitPoint * inverseVertexMatrix[2];
        if(baryC <  -0.1f) return false;

        if(ray.isShadowRay)
        {
                //faster way to tell
                lastTestedRayResult.isIntersect = true;
                lastTestedRayResult.depth               = depth;
                return true;
        }

        lastTestedRayResult.normal.setScaled(baryA, meshNormals[vertexIndices[0]]);
        lastTestedRayResult.normal.addScaled(baryB, meshNormals[vertexIndices[1]]);
        lastTestedRayResult.normal.addScaled(baryC, meshNormals[vertexIndices[2]]);
//      lastTestedRayResult.normal = flatNormal;

        lastTestedRayResult.texUV.setScaled(baryA, meshTexCoords[vertexIndices[0]]);
        lastTestedRayResult.texUV.addScaled(baryB, meshTexCoords[vertexIndices[1]]);
        lastTestedRayResult.texUV.addScaled(baryC, meshTexCoords[vertexIndices[2]]);

        lastTestedRayResult.isIntersect = true;
        lastTestedRayResult.depth               = depth;
        lastTestedRayResult.point               = hitPoint;
        return true;
}

void TriangleMesh::Patch::sampleSurface(Radion& radion)
{
        Vector u = meshVertices[vertexIndices[1]] - meshVertices[vertexIndices[0]];
        Vector v = meshVertices[vertexIndices[2]] - meshVertices[vertexIndices[0]];
        double r1 = (double)rand() / RAND_MAX;
        double r2 = (double)rand() / RAND_MAX;
        if(r1 + r2 > 1.0)
        {
                r1 = 1.0 - r1;
                r2 = 1.0 - r2;
        }
        radion.position = meshVertices[vertexIndices[0]] + u * r1 + v * r2;
        float baryA = (r1 + r2) * 0.5f;
        float baryB = (1.0f - r1) * 0.5f;
        float baryC = (1.0f - r2) * 0.5f;

        radion.normal.setScaled(baryA, meshNormals[vertexIndices[0]]);
        radion.normal.addScaled(baryB, meshNormals[vertexIndices[1]]);
        radion.normal.addScaled(baryC, meshNormals[vertexIndices[2]]);

        radion.radiance.setScaled(baryA, meshTexCoords[vertexIndices[0]]);
        radion.radiance.addScaled(baryB, meshTexCoords[vertexIndices[1]]);
        radion.radiance.addScaled(baryC, meshTexCoords[vertexIndices[2]]);

        if(radion.radiance.norm2() < 0.00001)
                bool mijafa = true;

//      radion.radiance.z = getSurfaceArea();
}

Vector* TriangleMesh::Patch::meshVertices = 0x0;
Vector* TriangleMesh::Patch::meshNormals = 0x0;
Vector* TriangleMesh::Patch::meshTexCoords = 0x0;

bool TriangleMesh::intersect (const Ray& ray, float& depth, float rayMin, float rayMax)
{
        lastTestedRayId = ray.id;
        lastTestedRayResult.isIntersect = false;
        Patch::meshNormals = normals;
        Patch::meshTexCoords = texCoords;
        HitRec hitRec;
        meshTree->traverse(ray, hitRec, rayMin, rayMax);
        lastTestedRayResult = hitRec;
        lastTestedRayResult.material = this->material;
        depth = lastTestedRayResult.depth;
        lastTestedRayResult.object = this;
        return lastTestedRayResult.isIntersect;
}

bool TriangleMesh::intersectBackSide (const Ray& ray, float& depth, float rayMin, float rayMax)
{
        lastTestedRayId = ray.id;
        lastTestedRayResult.isIntersect = false;
        Patch::meshNormals = normals;
        HitRec hitRec;
        meshTree->traverseBackSide(ray, hitRec, rayMin, rayMax);
//      meshTree->forbidden = hitRec.object;
        lastTestedRayResult = hitRec;
        lastTestedRayResult.material = this->material;
        depth = lastTestedRayResult.depth;
        lastTestedRayResult.object = this;
        return lastTestedRayResult.isIntersect;
}

TriangleMesh::~TriangleMesh(void)
{
        delete [] areaTree;
        delete meshTree;
        delete meshVertices;
        delete [] meshPatches;
        delete normals;
        delete texCoords;
}


double TriangleMesh::getPatchArea(unsigned int index)
{
        if(index >= nMeshPatches)
                return 0;
        Vector a = meshVertices[meshPatches[index].vertexIndices[1]] -
                        meshVertices[meshPatches[index].vertexIndices[0]];
        Vector b = meshVertices[meshPatches[index].vertexIndices[2]] -
                        meshVertices[meshPatches[index].vertexIndices[0]];
        return (a && b).norm();
}

double TriangleMesh::buildAreaTree(unsigned int u)
{
        if(u >= nAreaTreeNodes)
        {
                u -= nAreaTreeNodes;
                return getPatchArea(u);
        }
        areaTree[u] = buildAreaTree(u * 2 + 1) + buildAreaTree(u * 2 + 2);
        return areaTree[u];
}

void TriangleMesh::buildAreaTree()
{
        nAreaTreeNodes = 1;
        while(nAreaTreeNodes < nMeshPatches  )
                nAreaTreeNodes <<= 1;
        nAreaTreeNodes--;
        areaTree = new double[nAreaTreeNodes];
        surfaceArea = buildAreaTree(0);
}

void TriangleMesh::sampleSurface(unsigned int u, double rnd, Radion& radion)
{
        if(u >= nAreaTreeNodes)
        {
                u -= nAreaTreeNodes;
                if(u >= nMeshPatches)
                        u = 0;
                meshPatches[u].sampleSurface(radion);
                return;
        }
        float leftweight = 0.0f;
        if(u * 2 + 1 >= nAreaTreeNodes)
                leftweight = getPatchArea(u * 2 + 1 - nAreaTreeNodes);
        else
                leftweight = areaTree[u * 2 + 1];
        if(rnd <= leftweight)
                sampleSurface(u * 2 + 1, rnd, radion);
        else
                sampleSurface(u * 2 + 2, rnd - leftweight, radion);
}

void TriangleMesh::sampleSurface(Radion& radion)
{
        Patch::meshVertices = meshVertices;
        Patch::meshNormals = normals;
        Patch::meshTexCoords = texCoords;
        double rnd = surfaceArea * (double)rand() / RAND_MAX;
        sampleSurface(0, rnd, radion);
        radion.radiance.z = surfaceArea;
}

float TriangleMesh::getSurfaceArea()
{
        return surfaceArea;
}