[GM & AS-WIP] Listra Pathfinder Module

Subject: [GM & AS-WIP] Listra Pathfinder Module Wed Dec 08, 2010 2:12 pm

Sementara aku suka mempelajari Matematika Diskrit tentang Graf dan Pohon, aku pelajari algoritma pathfinding dan buat scriptnya dalam GML dan Flash. Okay, ini scriptnya

GML
2D Map Graph & Pathfinding Algorithms. Script ini untuk membangun graf dari matriks map dan melakukan pathfinding (mencari jalan terpendek karakter dari suatu posisi ke posisi tujuan)

Code:: #define dijkstra
/*
Dijkstra's Algorithm

@> Function
* To find a shortest path from starting vertex (s) to target vertex (t)
and return path distance from s to t.

@> Required Data
* n: number of grid vertices
* s: index of source vertex
* t: index of target vertex
* global.nb[u,i]: i-th neighbor of grid vertex u, whose distance from u
is 1 (as vertex index)
* global.tc[u,i]: terrain cost from u to global.nb[u,i]
(equal to 1 normally)
* global.neighbors: maximum number of each vertices (usually 4 for
4-directional movement or 8 for 8-directional movement)

@> Required Scripts
* remove(x): Removes x from array q (as priority queue)
* add(x): Inserts x into array q (as priority queue)
* u_nearest(): Returns index u of array q, where vertices_dist[u]
is smallest

@> Usage Guide
* For graph initialization, build a passage graph with script
buildGraph().
* Then use this script on a game character. Set its variables s as index of
the target's position vertex and t as index of the character's
position vertex.
* After that, you can trace the character's path by using vertices_prev[t].
* You can also use vertices_dist[t] or value returned by this script to
show the character's distance to the target.

@> Credits
* Bunga Tepi Jalan (bungatepijalan.wordpress.com)
* Wikipedia

@> Notes
* If you want to learn more about Dijkstra's algorithm, see the article at:
http://en.wikipedia.org/wiki/Dijkstra's_algorithm
* The path constructed by this algorithm is always the shortest.
* This script is made based on pseudocode at that article, with
improvement on efficiency.
*/

// Initializations
nq=0 // Create open list q (as priority queue)
add(s) // Add s into open list q
for(i=1;i<=n;i+=1){
vertices_dist[i]=9999 // Unknown distance function from source to v
vertices_prev[i]=0 // Previous node in optimal path from source
}
vertices_dist[s]=0 // Distance from source to source
while(nq>0){ // The main loop
//Finds vertex u with least value of path distance
u_nearest()
dist_u=vertices_dist[u]
if(u==t){
//If u is the target, search completed and returns its distance.
//You can add statements here, usually to read/construct path
return dist_u
}
remove(u)
for(i=1;i<=global.neighbors;i+=1){
v=global.nb[u,i] // where v has not yet been removed from Q.
if(v!=0){
alt=dist_u+global.tc[u,i]
if(alt<vertices_dist[v]){ // Relax (u,v)
add(v)
vertices_dist[v]=alt
vertices_prev[v]=u
}
}
}
}
//Statements below this will be executed if all remaining vertices
//are inaccessible from source. This means that target vertex is isolated
//from source vertex. Also means that vertices_dist[t]==9999.
//You can add them here, usually to alert that no path is found.

#define BFS
/*
Best-first Search (BFS)

@> Function
* To find a path from starting vertex (s) to target vertex (t).

@> Required Data
* n: number of grid vertices
* s: index of source vertex
* t: index of target vertex
* global.nb[u,i]: i-th neighbor of grid vertex u, whose distance from u
is 1 (as vertex index)
* global.tc[u,i]: terrain cost from u to global.nb[u,i]
(equal to 1 normally)
* global.neighbors: maximum number of each vertices (usually 4 for
4-directional movement or 8 for 8-directional movement)

@> Required Scripts
* remove(x): Removes x from array q (as priority queue)
* add(x): Inserts x into array q (as priority queue)
* u_nearest3(): Returns index u of array q, where h_score[u]
is smallest
* findHeuristic(x,y): Returns heuristic (estimated) distance from
vertex x to y

@> Usage Guide
* For graph initialization, build a passage graph with script
buildGraph().
* Then use this script on a game character. Set its variables s as index of
the target's position vertex and t as index of the character's
position vertex.
* After that, you can trace the character's path by using vertices_prev[t].
* You can also use vertices_dist[t] or value returned by this script to
show the character's distance to the target.

@> Credits
* Bunga Tepi Jalan (bungatepijalan.wordpress.com)
* Wikipedia

@> Notes
* If you want to learn more about Best-first Search, see the article at:
http://en.wikipedia.org/wiki/Best-first_search
* The constructed path isn't always the shortest path. If you want to find
the shortest path, don't use this.
*/

// Initializations
nq=0 // Create open list q (as priority queue)
add(s) // Add s into open list q
for(i=1;i<=n;i+=1){
q1[i]=0 // Create closed list q1, The list of nodes already evaluated.
vertices_prev[i]=0 // The map of navigated nodes.
}
vertices_dist[s]=0
h_score[s]=findHeuristic(s,t) // Heuristic distance
while(nq>0){ // while the open list is not empty
u_nearest3()
if(u==t){
//If u is the target, search completed and returns its distance.
//You can add statements here, usually to read/construct path
return 0
}
remove(u)
q1[u]=1 // move current node from open list to the closed list
for(i=1;i<=global.neighbors;i+=1){
v=global.nb[u,i] // successor of u
if(v!=0){
if(!q1[v]){
add(v)
vertices_dist[v]=vertices_dist[u]+global.tc[u,i]
h_score[v]=findHeuristic(v,t)
vertices_prev[v]=u
}else{
if(vertices_dist[v]>vertices_dist[u]+global.tc[u,i]){
vertices_dist[v]=vertices_dist[u]+global.tc[u,i]
vertices_prev[v]=u
}
}
}
}
}
//Statements below this will be executed if all remaining vertices
//are inaccessible from source. This means that target vertex is isolated
//from source vertex.
//You can add them here, usually to alert that no path is found.

#define AStar
/*
A* Algorithm

@> Function
* To find a shortest path from starting vertex (s) to target vertex (t)
and return path distance from s to t.

@> Required Data
* n: number of grid vertices
* s: index of source vertex
* t: index of target vertex
* global.nb[u,i]: i-th neighbor of grid vertex u, whose distance from u
is 1 (as vertex index)
* global.tc[u,i]: terrain cost from u to global.nb[u,i]
(equal to 1 normally)
* global.neighbors: maximum number of each vertices (usually 4 for
4-directional movement or 8 for 8-directional movement)

@> Required Scripts
* remove(x): Removes x from array q (as priority queue)
* add(x): Inserts x into array q (as priority queue)
* found(x): Returns whether x is in array q
* u_nearest2(): Returns index u of array q, where f_score[u]
is smallest
* findHeuristic(x,y): Returns heuristic (estimated) distance from
vertex x to y

@> Usage Guide
* For graph initialization, build a passage graph with script
buildGraph().
* Then use this script on a game character. Set its variables s as index of
the target's position vertex and t as index of the character's
position vertex.
* After that, you can trace the character's path by using vertices_prev[t].
* You can also use vertices_dist[t] or value returned by this script to
show the character's distance to the target.

@> Credits
* Bunga Tepi Jalan (bungatepijalan.wordpress.com)
* Wikipedia
* Amit's A* Pages (http://www-cs-students.stanford.edu/~amitp/gameprog.html)

@> Notes
* If you want to learn more about A* Algorithm, see the article at:
http://en.wikipedia.org/wiki/A*_search_algorithm
* A* is the best choice for pathfinding. Recommended to use this on
most purposes.
*/

// Initializations
nq=0 // Create open list q (as priority queue)
add(s) // Add s into open list q
for(i=1;i<=n;i+=1){
q1[i]=0 // Create closed list q1, The list of nodes already evaluated.
vertices_prev[i]=0 // The map of navigated nodes.
}
vertices_dist[s]=0 // Distance from start along optimal path.
h_score[s]=findHeuristic(s,t) // Heuristic distance
f_score[s]=h_score[s] // Estimated total distance from start to goal.
while(nq>0){ // while the open list is not empty
u_nearest2()
if(u==t){
//If u is the target, search completed and returns its distance.
//You can add statements here, usually to read/construct path
return dist_u
}
remove(u)
q1[u]=1 // move current node from open list to the closed list
for(i=1;i<=global.neighbors;i+=1){
v=global.nb[u,i]
if(v!=0){
if(!q1[v]){
tentative_g_score=vertices_dist[u]+global.tc[u,i]
if(!found(v)){
add(v)
tentative_is_better=true
}else if(tentative_g_score<vertices_dist[v]){
tentative_is_better=true
}else{
tentative_is_better=false
}
if(tentative_is_better){
if(vertices_prev[v]!=0){
if(f_score[u]<f_score[vertices_prev[v]]){
vertices_prev[v]=u
}
}else{
vertices_prev[v]=u
}
vertices_dist[v]=tentative_g_score
h_score[v]=findHeuristic(v,t)
f_score[v]=vertices_dist[v]+h_score[v]
}
}
}
}
}
//Statements below this will be executed if all remaining vertices
//are inaccessible from source. This means that target vertex is isolated
//from source vertex.
//You can add them here, usually to alert that no path is found.

#define remove
//remove(ii)
//Removes an element with value ii from priority queue q
ii=argument0
iii=1
while(iii<=nq && q[iii]!=ii){
iii+=1
}
iv=iii;
if(iv<=nq){
if(iv<nq){
for(iii=iv;iii<=nq-1;iii+=1){
q[iii]=q[iii+1];
}
}
nq=nq-1;
}

#define add
//add(ii)
//Inserts an element with value ii into priority queue q
ii=argument0
if(nq==0){
q[1]=ii
}else{
iii=1
while(iii<=nq && q[iii]<ii){
iii+=1
}
iv=iii
if(iv<=nq){
for(iii=nq;iii>=iv;iii-=1){
q[iii+1]=q[iii]
}
}
q[iv]=ii
}
nq+=1

#define found
//found(ii)
//Returns whether element ii is in priority queue q
ii=argument0
ff=false;
if(nq>0){
for(iii=1;iii<=nq;iii+=1){
if(q[iii]==ii){
ff=true
break
}
}
}
return ff;

#define u_nearest
//u_nearest()
//Returns index u of array q, where vertices_dist[u] is smallest
d=vertices_dist[q[1]]
u=q[1]
if(nq>1){
for(ii=2;ii<=nq;ii+=1){
if(vertices_dist[q[ii]]<d){
d=vertices_dist[q[ii]];
u=q[ii];
}
}
}

#define u_nearest2
//u_nearest2()
//Returns index u of array q, where f_score[u] is smallest
if(nq>0){
d=f_score[q[1]]
u=q[1]
if(nq>1){
for(ii=2;ii<=nq;ii+=1){
if(f_score[q[ii]]<d){
d=f_score[q[ii]];
u=q[ii];
}
}
}
}

#define u_nearest3
//u_nearest3()
//Returns index u of array q, where h_score[u] is smallest
if(nq>0){
d=h_score[q[1]]
u=q[1]
if(nq>1){
for(ii=2;ii<=nq;ii+=1){
if(h_score[q[ii]]<d){
d=h_score[q[ii]];
u=q[ii];
}
}
}
}

#define findHeuristic
//findHeuristic(x,y)
//Calculates heuristic distance between vertex x and vertex y
dx=((argument1-1) div global.w)-((argument0-1) div global.w)
dy=((argument1-1) mod global.w)-((argument0-1) mod global.w)
//Uncomment one of two statements below to select a heuristic formula
//you want to use
return sqrt(dx*dx+dy*dy) //Euclidean distance heuristic
//return (dx+dy) //Manhattan distance heuristic

#define buildGraph
/*
buildGraph()

@> Function
* To generate a passage graph of given 2-dimensional map.

@> Required Data
* global.M[i,j]: Terrain type of cell of map matrix at row i and column j.
Obstacles have terrain type 0.
* global.passable[i]: The value is 0 if i is type of obstacle. Otherwise,
determines terrain cost of terrain type i (normally 1).
* h: number of rows of the map matrix
* w: number of columns of the map matrix

@> Outputs
* global.nb[u,i]: i-th neighbor of grid vertex u, whose distance from u
is 1 (as vertex index)
* global.tc[u,i]: terrain cost from u to global.nb[u,i]
(equal to 1 normally)

@> Usage Guide
* From a terrain map, build 2-dimensional map matrix global.M, and then use
this script to generate a passage graph.

@> Credits
* Bunga Tepi Jalan (bungatepijalan.wordpress.com)
*/
global.neighbors=4
//Maximum number of neighbors of each vertices.
//You can change the value to: 4 for 4-directional movement, or 8 for
//8-directional movement
for(i=0;i<h;i+=1){
for(j=0;j<w;j+=1){
if(global.passable[global.M[i,j]]>0){
node=i*w+j
for(k=1;k<=4;k+=1){
global.nb[node+1,k]=0
}
//West
if(j>0){
if(global.passable[global.M[i,j-1]]>0){
global.nb[node+1,1]=node
global.tc[node+1,1]=global.passable[global.M[i,j]]
}
}
//East
if(j<w){
if(global.passable[global.M[i,j+1]]>0){
global.nb[node+1,2]=node+2
global.tc[node+1,2]=global.passable[global.M[i,j]]
}
}
//North
if(i>0){
if(global.passable[global.M[i-1,j]]>0){
global.nb[node+1,3]=node-w+1
global.tc[node+1,3]=global.passable[global.M[i,j]]
}
}
//South
if(i<h){
if(global.passable[global.M[i+1,j]]>0){
global.nb[node+1,4]=node+w+1
global.tc[node+1,4]=global.passable[global.M[i,j]]
}
}
if(global.neighbors==8){
//Northwest
if(i>0 && j>0){
if(global.passable[global.M[i-1,j-1]]>0){
global.nb[node+1,1]=node-w
global.tc[node+1,1]=global.passable[global.M[i,j]]*sqrt(2)
}
}
//Northeast
if(i>0 && j<w){
if(global.passable[global.M[i-1,j+1]]>0){
global.nb[node+1,1]=node-w+2
global.tc[node+1,1]=global.passable[global.M[i,j]]*sqrt(2)
}
}
//Southwest
if(i<h && j>0){
if(global.passable[global.M[i+1,j-1]]>0){
global.nb[node+1,1]=node+w
global.tc[node+1,1]=global.passable[global.M[i,j]]*sqrt(2)
}
}
//Southeast
if(i<h && j<w){
if(global.passable[global.M[i+1,j+1]]>0){
global.nb[node+1,1]=node+w+2
global.tc[node+1,1]=global.passable[global.M[i,j]]*sqrt(2)
}
}
}
}
}
}

Tambahan: Maze Generation Algorithms. Script ini untuk membuat maze secara acak. Inputnya cukup dengan graf dari map kosong.
NB: Pakai saja Recursive Backtracker buat bikin maze yang lebih susah.

Code:: #define DFSBacktracker
/*
Recursive Backtracker (using Depth-first Search)

Required data
* s: current cell
* global.nb[u,i]: i-th neighbor of cell u (1<=i<=4), whose distance
from u is 1
*/

// Initializations
nq=global.n
for(i=1;i<=global.n;i+=1){
q[i]=0
prev[i]=0
}
u=s
while(nq>=0){
if(!q[u]){
q[u]=1 //Mark the current cell as 'Visited'
nq-=1
}
avail=false
for(i=1;i<=4;i+=1){
if(global.nb1[u,i]!=0){
avail=(avail || !q[global.nb1[u,i]])
}
}
//If the current cell has any neighbours which have not been visited
if(avail){
//Choose randomly one of the unvisited neighbours
do{
j=1+irandom(3)
v=global.nb1[u,j]
}until(!q[v])
prev[v]=u
//remove the wall between the current cell and the chosen cell
global.nb[u,j]=v
if(j==1){
j=2
}else if(j==2){
j=1
}else if(j==3){
j=4
}else if(j==4){
j=3
}
global.nb[v,j]=u
//Make the chosen cell the current cell, and
//repeat the search until all cells visited
u=v
}else{
//Make previously chosen cell the current cell (backtrack)
if(prev[u]!=0){
u=prev[u]
}
}
}

#define HuntNKill
/*
Hunt and Kill

Required data
* s: current cell
* global.nb[u,i]: i-th neighbor of cell u (1<=i<=4), whose distance
from u is 1
*/

// Initializations
nq=global.n
for(i=1;i<=global.n;i+=1){
q[i]=0
}
u=s
while(nq>=0){
if(!q[u]){
q[u]=1 //Mark the current cell as 'Visited'
nq-=1
}
avail=false
for(i=1;i<=4;i+=1){
if(global.nb1[u,i]!=0){
avail=(avail || !q[global.nb1[u,i]])
}
}
//If the current cell has any neighbours which have not been visited
if(avail){
//Choose randomly one of the unvisited neighbours
do{
j=1+irandom(3)
v=global.nb1[u,j]
}until(!q[v])
//remove the wall between the current cell and the chosen cell
global.nb[u,j]=v
if(j==1){
j=2
}else if(j==2){
j=1
}else if(j==3){
j=4
}else if(j==4){
j=3
}
global.nb[v,j]=u
//Make the chosen cell the current cell, and
//repeat the search until all cells visited
u=v
}else{
//Hunt!
do{
u=1+irandom(global.n-1)
}until(q[u])
}
}

#define Prim
/*
Prim's Algorithm

Required data
* s: index of source vertex
* global.nb[u,i]: i-th neighbor of grid vertex u (1<=i<=4), whose distance
from u is 1
*/

// Initializations
nq=0
for(i=1;i<=global.n;i+=1){
q1[i]=0
}
u=1+irandom(global.n-1)
q1[u]=1
add(u)
while(nq<=global.n){
avail=false
for(i=1;i<=4;i+=1){
if(global.nb1[u,i]!=0){
avail=(avail || !q1[global.nb1[u,i]])
}
}
//If the current cell has any neighbours which have not been visited
if(avail){
//Choose randomly one of the unvisited neighbours
do{
j=1+irandom(3)
v=global.nb1[u,j]
}until(!q1[v])
q1[v]=1
add(v)
//remove the wall between the current cell and the chosen cell
global.nb[u,j]=v
if(j==1){
j=2
}else if(j==2){
j=1
}else if(j==3){
j=4
}else if(j==4){
j=3
}
global.nb[v,j]=u
}
i=1+irandom(nq-1)
u=q[i]
}

Save kedua code tsb dalam .gml dan tinggal pilih Import All Scripts aja

Flash
MGraph.as : Translate-an dari GML diatas utk algoritma2 pathfinding.

Code:: /*
*==============================================================================
* ## MGraph (Map Graph)
*------------------------------------------------------------------------------
* This class generates a passage graph of given 2-dimensional map and uses it
* for pathfinding analysis with Dijkstra's algorithm and A*.
*------------------------------------------------------------------------------
* Usage Guide
*------------------------------------------------------------------------------
* Build a 2-dimensional map matrix global.M, and then use
* the constructor to generate a passage graph.
*------------------------------------------------------------------------------
* Credits
*------------------------------------------------------------------------------
* Bunga Tepi Jalan (bungatepijalan.wordpress.com)
* Wikipedia
*==============================================================================
*/
import PQueue;
class MGraph {
private var n, h, w, neighbors:Number;
private var nb, tc, passable, vertices_dist, vertices_next:Array;
function MGraph(M, pass:Array, nh:Number) {
   h = M.length;
   w = M[0].length;
   n = h*w;
   neighbors = nh;
   passable = pass;
   nb = new Array(n+1);
   tc = new Array(n+1);
   var node;
   for (var i = 0; i<h; i += 1) {
      for (var j = 0; j<w; j += 1) {
         if (passable[M[i][j]]>0) {
            node = i*w+j;
            nb[node+1] = new Array();
            tc[node+1] = new Array();
            for (var k = 1; k<=neighbors+1; k += 1) {
               nb[node+1].push(0);
               tc[node+1].push(0);
            }
            //West
            if (j>0) {
               if (passable[M[i][j-1]]>0) {
                  nb[node+1][1] = node;
                  tc[node+1][1] = passable[M[i][j]];
               }
            }
            //East
            if (j<w) {
               if (passable[M[i][j+1]]>0) {
                  nb[node+1][2] = node+2;
                  tc[node+1][2] = passable[M[i][j]];
               }
            }
            //North
            if (i>0) {
               if (passable[M[i-1][j]]>0) {
                  nb[node+1][3] = node-w+1;
                  tc[node+1][3] = passable[M[i][j]];
               }
            }
            //South
            if (i<h) {
               if (passable[M[i+1][j]]>0) {
                  nb[node+1][4] = node+w+1;
                  tc[node+1][4] = passable[M[i][j]];
               }
            }
            if (neighbors == 8) {
               //Northwest
               if (i>0 && j>0) {
                  if (passable[M[i-1][j-1]]>0) {
                     nb[node+1][5] = node-w;
                     tc[node+1][5] = passable[M[i][j]]*Math.sqrt(2);
                  }
               }
               //Northeast
               if (i>0 && j<w) {
                  if (passable[M[i-1][j+1]]>0) {
                     nb[node+1][6] = node-w+2;
                     tc[node+1][6] = passable[M[i][j]]*Math.sqrt(2);
                  }
               }
               //Southwest
               if (i<h && j>0) {
                  if (passable[M[i+1][j-1]]>0) {
                     nb[node+1][7] = node+w;
                     tc[node+1][7] = passable[M[i][j]]*Math.sqrt(2);
                  }
               }
               //Southeast
               if (i<h && j<w) {
                  if (passable[M[i+1][j+1]]>0) {
                     nb[node+1][8] = node+w+2;
                     tc[node+1][8] = passable[M[i][j]]*Math.sqrt(2);
                  }
               }
            }
         }
      }
   }
}
function findHeuristic(x1, y1, x2, y2:Number) {
   return Math.sqrt((x2-x1)*(x2-x1)+(y2-y1)*(y2-y1));
}
public function dijkstra(x1, y1, x2, y2:Number) {
   // Initializations
   var s = y1*w+x1+1;
   var t = y2*w+x2+1;
   var q = [0];// Create open list q (as priority queue)
   q = PQueue.add(q, s);// Add s into open list q
   vertices_dist = new Array();
   var vertices_prev = new Array();
   vertices_next = new Array();
   for (var i = 0; i<=n; i++) {
      vertices_dist.push(9999);// Unknown distance function from source to v
      vertices_prev.push(0);// Previous node in optimal path from source
      vertices_next.push(0);
   }
   vertices_dist[s] = 0;// Distance from source to source
   var u, v, alt;
   while (q.length>1) {// The main loop
      //Finds vertex u with least value of path distance
      var d = vertices_dist[q[1]];
      u = q[1];
      if (q.length>1) {
         for (var ii = 2; ii<=q.length; ii++) {
            if (vertices_dist[q[ii]]<d) {
               d = vertices_dist[q[ii]];
               u = q[ii];
            }
         }
      }
      if (u == t) {
         //If u is the target, search completed and returns its distance.
         //You can add statements here, usually to read/construct path
         while (vertices_prev[u] != s && vertices_prev[u] != 0) {
            vertices_next[vertices_prev[u]] = u;
            u = vertices_prev[u];
         }
         vertices_next[s] = u;
         return vertices_dist[t];
      }
      q = PQueue.remove(q, u);
      for (var i = 1; i<=neighbors; i++) {
         v = nb[u][i];// where v has not yet been removed from Q.
         if (v != 0) {
            alt = vertices_dist[u]+tc[u][i];
            if (alt<vertices_dist[v]) {// Relax (u,v)
               q = PQueue.add(q, v);
               vertices_dist[v] = alt;
               vertices_prev[v] = u;
            }
         }
      }
   }
   //Statements below this will be executed if all remaining vertices
   //are inaccessible from source. This means that target vertex is isolated
   //from source vertex. Also means that vertices_dist[t]==9999.
   //You can add them here, usually to alert that no path is found.
}
public function AStar(x1, y1, x2, y2:Number) {
   // Initializations
   var s = y1*w+x1+1;
   var t = y2*w+x2+1;
   var q = [0];// Create open list q (as priority queue)
   var q1 = new Array();// Create closed list q1, The list of nodes already evaluated.
   q = PQueue.add(q, s);// Add s into open list q
   vertices_dist = new Array();
   var vertices_prev = new Array();
   vertices_next = new Array();
   var h_score = new Array();
   var f_score = new Array();
   for (var i = 0; i<=n; i++) {
      q1.push(0);
      vertices_dist.push(9999);// Unknown distance function from source to v
      h_score.push(0);
      f_score.push(0);
      vertices_prev.push(0);// Previous node in optimal path from source
      vertices_next.push(0);
   }
   vertices_dist[s] = 0;// Distance from start along optimal path.
   h_score[s] = findHeuristic(x1, y1, x2, y2);// Heuristic distance
   f_score[s] = h_score[s];// Estimated total distance from start to goal.
   var u, v, alt, tentative_g_score, tentative_is_better;
   while (q.length>1) {// The main loop
      //Finds vertex u with least value of path distance
      var d = f_score[q[1]];
      u = q[1];
      if (q.length>1) {
         for (var ii = 2; ii<=q.length; ii++) {
            if (f_score[q[ii]]<d) {
               d = f_score[q[ii]];
               u = q[ii];
            }
         }
      }
      if (u == t) {
         //If u is the target, search completed and returns its distance.
         //You can add statements here, usually to read/construct path
         while (vertices_prev[u] != s && vertices_prev[u] != 0) {
            vertices_next[vertices_prev[u]] = u;
            u = vertices_prev[u];
         }
         vertices_next[s] = u;
         return vertices_dist[t];
      }
      q = PQueue.remove(q, u);
      q1[u] = 1;
      for (var i = 1; i<=neighbors; i++) {
         v = nb[u][i];// where v has not yet been removed from Q.
         if (v != 0) {
            if (!q1[v]) {
               tentative_g_score = vertices_dist[u]+tc[u][i];
               if (!PQueue.found(q, v)) {
                  q = PQueue.add(q, v);
                  tentative_is_better = true;
               } else if (tentative_g_score<vertices_dist[v]) {
                  tentative_is_better = true;
               } else {
                  tentative_is_better = false;
               }
               if (tentative_is_better) {
                  if (vertices_prev[v] != 0) {
                     if (f_score[u]<f_score[vertices_prev[v]]) {
                        vertices_prev[v] = u;
                     }
                  } else {
                     vertices_prev[v] = u;
                  }
                  vertices_dist[v] = tentative_g_score;
                  h_score[v] = findHeuristic(Math.floor((v-1)/w), (v-1)%w, x2, y2);
                  f_score[v] = vertices_dist[v]+h_score[v];
               }
            }
         }
      }
   }
   //Statements below this will be executed if all remaining vertices
   //are inaccessible from source. This means that target vertex is isolated
   //from source vertex. Also means that vertices_dist[t]==9999.
   //You can add them here, usually to alert that no path is found.
}
public function get _h() {
   return h;
}
public function get _w() {
   return w;
}
public function nextp(x:Number) {
   return vertices_next[x];
}
}

Scripts + Test Drivers Downloads (Beta)
GML: http://ifile.it/o5bm9vx/GSA.zip
Flash: http://ifile.it/kynuj73/GSAFlash.zip

Test Driver Demo Screenshot

Awas gede!:

Scriptku masih lom benar2 selesai, tapi semoga bermanfaat buat game RPG-mu

Rencananya kalo uda selesai, script ini nanti bakal ditranslate ke RGSS dan XNA (kalo uda belajar cukup

)

Subject: Re: [GM & AS-WIP] Listra Pathfinder Module Thu Dec 30, 2010 3:17 pm

Tambahan! :lkabur:
Script LPM dalam XNA, codingannya lihat di: http://listra.pastebay.com/112916
Disitu jg lebih lengkap, dengan fitur scroll map yang lebih smooth.

Cara pemasangan?
- Buat project XNA baru dengan nama GSADemo
- Tambahkan resource sprite (dlm PNG) dengan asset name "listra10_strip4" (charset ukuran 128x192) dan "sprite_wall_corner" (sprite kotak ukuran 32x32)
- Buat file script class baru dengan nama MGraph.cs , PQueue.cs , Chara.cs , GameView.cs selain Game1.cs
- Copas setiap bagian codingan script ke masing-masing file script tersebut.

Download demo project: http://ifile.it/jh4l2wa/GSAdemo.zip
Gratis sprite charset Listra disitu!!!

:kabur: