progmesh_8C_source.html

/*

 *  Progressive Mesh type Polygon Reduction Algorithm

 *  by Stan Melax (c) 1998

 *  Permission to use any of this code wherever you want is granted..

 *  Although, please do acknowledge authorship if appropriate.

 *

 *  See the header file progmesh.h for a description of this module

 */


#include <stdio.h>

#include <math.h>

#include <stdlib.h>

#include <assert.h>

//#include <windows.h>


#include "vector.h"

#include "list.h"

#include "progmesh.h"


#define min(x,y) (((x) <= (y)) ? (x) : (y))

#define max(x,y) (((x) >= (y)) ? (x) : (y))


/*

 *  For the polygon reduction algorithm we use data structures

 *  that contain a little bit more information than the usual

 *  indexed face set type of data structure.

 *  From a vertex we wish to be able to quickly get the

 *  neighboring faces and vertices.

 */

class Triangle;

class Vertex;


class Triangle {

  public:

        Vertex *         vertex[3]; // the 3 points that make this tri

        Vector           normal;    // unit vector othogonal to this face

                         Triangle(Vertex *v0,Vertex *v1,Vertex *v2);

                         ~Triangle();

        void             ComputeNormal();

        void             ReplaceVertex(Vertex *vold,Vertex *vnew);

        int              HasVertex(Vertex *v);

};

class Vertex {

  public:

        Vector           position; // location of point in euclidean space

        int              id;       // place of vertex in original list

        List<Vertex *>   neighbor; // adjacent vertices

        List<Triangle *> face;     // adjacent triangles

        float            objdist;  // cached cost of collapsing edge

        Vertex *         collapse; // candidate vertex for collapse

                         Vertex(Vector v,int _id);

                         ~Vertex();

        void             RemoveIfNonNeighbor(Vertex *n);

};

List<Vertex *>   vertices;

List<Triangle *> triangles;


Triangle::Triangle(Vertex *v0,Vertex *v1,Vertex *v2){

        assert(v0!=v1 && v1!=v2 && v2!=v0);

        vertex[0]=v0;

        vertex[1]=v1;

        vertex[2]=v2;

        ComputeNormal();

        triangles.Add(this);

        for(int i=0;i<3;i++) {

                vertex[i]->face.Add(this);

                for(int j=0;j<3;j++) if(i!=j) {

                        vertex[i]->neighbor.AddUnique(vertex[j]);

                }

        }

}

Triangle::~Triangle(){

        int i;

        triangles.Remove(this);

        for(i=0;i<3;i++) {

                if(vertex[i]) vertex[i]->face.Remove(this);

        }

        for(i=0;i<3;i++) {

                int i2 = (i+1)%3;

                if(!vertex[i] || !vertex[i2]) continue;

                vertex[i ]->RemoveIfNonNeighbor(vertex[i2]);

                vertex[i2]->RemoveIfNonNeighbor(vertex[i ]);

        }

}

int Triangle::HasVertex(Vertex *v) {

        return (v==vertex[0] ||v==vertex[1] || v==vertex[2]);

}

void Triangle::ComputeNormal(){

        Vector v0=vertex[0]->position;

        Vector v1=vertex[1]->position;

        Vector v2=vertex[2]->position;

        normal = (v1-v0)*(v2-v1);

        if(magnitude(normal)==0)return;

        normal = normalize(normal);

}

void Triangle::ReplaceVertex(Vertex *vold,Vertex *vnew) {

        assert(vold && vnew);

        assert(vold==vertex[0] || vold==vertex[1] || vold==vertex[2]);

        assert(vnew!=vertex[0] && vnew!=vertex[1] && vnew!=vertex[2]);

        if(vold==vertex[0]){

                vertex[0]=vnew;

        }

        else if(vold==vertex[1]){

                vertex[1]=vnew;

        }

        else {

                assert(vold==vertex[2]);

                vertex[2]=vnew;

        }

        int i;

        vold->face.Remove(this);

        assert(!vnew->face.Contains(this));

        vnew->face.Add(this);

        for(i=0;i<3;i++) {

                vold->RemoveIfNonNeighbor(vertex[i]);

                vertex[i]->RemoveIfNonNeighbor(vold);

        }

        for(i=0;i<3;i++) {

                assert(vertex[i]->face.Contains(this)==1);

                for(int j=0;j<3;j++) if(i!=j) {

                        vertex[i]->neighbor.AddUnique(vertex[j]);

                }

        }

        ComputeNormal();

}


Vertex::Vertex(Vector v,int _id) {

        position =v;

        id=_id;

        vertices.Add(this);

}


Vertex::~Vertex(){

        assert(face.num==0);

        while(neighbor.num) {

                neighbor[0]->neighbor.Remove(this);

                neighbor.Remove(neighbor[0]);

        }

        vertices.Remove(this);

}

void Vertex::RemoveIfNonNeighbor(Vertex *n) {

        // removes n from neighbor list if n isn't a neighbor.

        if(!neighbor.Contains(n)) return;

        for(int i=0;i<face.num;i++) {

                if(face[i]->HasVertex(n)) return;

        }

        neighbor.Remove(n);

}


float ComputeEdgeCollapseCost(Vertex *u,Vertex *v) {

        // if we collapse edge uv by moving u to v then how

        // much different will the model change, i.e. how much "error".

        // Texture, vertex normal, and border vertex code was removed

        // to keep this demo as simple as possible.

        // The method of determining cost was designed in order

        // to exploit small and coplanar regions for

        // effective polygon reduction.

        // Is is possible to add some checks here to see if "folds"

        // would be generated.  i.e. normal of a remaining face gets

        // flipped.  I never seemed to run into this problem and

        // therefore never added code to detect this case.

        int i;

        float edgelength = magnitude(v->position - u->position);

        float curvature=0;


        // find the "sides" triangles that are on the edge uv

        List<Triangle *> sides;

        for(i=0;i<u->face.num;i++) {

                if(u->face[i]->HasVertex(v)){

                        sides.Add(u->face[i]);

                }

        }

        // use the triangle facing most away from the sides

        // to determine our curvature term

        for(i=0;i<u->face.num;i++) {

                float mincurv=1; // curve for face i and closer side to it

                for(int j=0;j<sides.num;j++) {

                        // use dot product of face normals. '^'

                        // defined in vector

                        float dotprod = u->face[i]->normal ^ sides[j]->normal;

                        mincurv = min(mincurv,(1-dotprod)/2.0f);

                }

                curvature = max(curvature,mincurv);

        }

        // the more coplanar the lower the curvature term

        return edgelength * curvature;

}


void ComputeEdgeCostAtVertex(Vertex *v) {

        // compute the edge collapse cost for all edges that start

        // from vertex v.  Since we are only interested in reducing

        // the object by selecting the min cost edge at each step, we

        // only cache the cost of the least cost edge at this vertex

        // (in member variable collapse) as well as the value of the

        // cost (in member variable objdist).

        if(v->neighbor.num==0) {

                // v doesn't have neighbors so it costs nothing to collapse

                v->collapse=NULL;

                v->objdist=-0.01f;

                return;

        }

        v->objdist = 1000000;

        v->collapse=NULL;

        // search all neighboring edges for "least cost" edge

        for(int i=0;i<v->neighbor.num;i++) {

                float dist;

                dist = ComputeEdgeCollapseCost(v,v->neighbor[i]);

                if(dist<v->objdist) {

                        // candidate for edge collapse

                        v->collapse=v->neighbor[i];

                        // cost of the collapse

                        v->objdist=dist;

                }

        }

}

void ComputeAllEdgeCollapseCosts() {

        // For all the edges, compute the difference it would make

        // to the model if it was collapsed.  The least of these

        // per vertex is cached in each vertex object.

        for(int i=0;i<vertices.num;i++) {

                ComputeEdgeCostAtVertex(vertices[i]);

        }

}


void Collapse(Vertex *u,Vertex *v){

        // Collapse the edge uv by moving vertex u onto v

        // Actually remove tris on uv, then update tris that

        // have u to have v, and then remove u.

        if(!v) {

                // u is a vertex all by itself so just delete it

                delete u;

                return;

        }

        int i;

        List<Vertex *>tmp;

        // make tmp a list of all the neighbors of u

        for(i=0;i<u->neighbor.num;i++) {

                tmp.Add(u->neighbor[i]);

        }

        // delete triangles on edge uv:

        for(i=u->face.num-1;i>=0;i--) {

                if(u->face[i]->HasVertex(v)) {

                        delete(u->face[i]);

                }

        }

        // update remaining triangles to have v instead of u

        for(i=u->face.num-1;i>=0;i--) {

                u->face[i]->ReplaceVertex(u,v);

        }

        delete u;

        // recompute the edge collapse costs for neighboring vertices

        for(i=0;i<tmp.num;i++) {

                ComputeEdgeCostAtVertex(tmp[i]);

        }

}


void AddVertex(List<Vector> &vert){

        for(int i=0;i<vert.num;i++) {

                new Vertex(vert[i],i);

        }

}

void AddFaces(List<tridata> &tri){

        for(int i=0;i<tri.num;i++) {

                new Triangle(

            vertices[tri[i].v[0]],

            vertices[tri[i].v[1]],

            vertices[tri[i].v[2]] );

        }

}


Vertex *MinimumCostEdge(){

        // Find the edge that when collapsed will affect model the least.

        // This funtion actually returns a Vertex, the second vertex

        // of the edge (collapse candidate) is stored in the vertex data.

        // Serious optimization opportunity here: this function currently

        // does a sequential search through an unsorted list :-(

        // Our algorithm could be O(n*lg(n)) instead of O(n*n)

        Vertex *mn=vertices[0];

        for(int i=0;i<vertices.num;i++) {

                if(vertices[i]->objdist < mn->objdist) {

                        mn = vertices[i];

                }

        }

        return mn;

}


void ProgressiveMesh(List<Vector> &vert, List<tridata> &tri,

                     List<int> &map, List<int> &permutation)

{

        AddVertex(vert);  // put input data into our data structures

        AddFaces(tri);

        ComputeAllEdgeCollapseCosts(); // cache all edge collapse costs

        permutation.SetSize(vertices.num);  // allocate space

        map.SetSize(vertices.num);          // allocate space

        // reduce the object down to nothing:

        while(vertices.num > 0) {

                // get the next vertex to collapse

                Vertex *mn = MinimumCostEdge();

                // keep track of this vertex, i.e. the collapse ordering

                permutation[mn->id]=vertices.num-1;

                // keep track of vertex to which we collapse to

                map[vertices.num-1] = (mn->collapse)?mn->collapse->id:-1;

                // Collapse this edge

                Collapse(mn,mn->collapse);

        }

        // reorder the map list based on the collapse ordering

        for(int i=0;i<map.num;i++) {

                map[i] = (map[i]==-1)?0:permutation[map[i]];

        }

        // The caller of this function should reorder their vertices

        // according to the returned "permutation".

}