void pathlib_deletepath(entity start) { entity e; e = findchainentity(owner, start); while(e) { e.think = SUB_Remove; e.nextthink = time; e = e.chain; } } //#define PATHLIB_NODEEXPIRE 0.05 #define PATHLIB_NODEEXPIRE 20 void dumpnode(entity n) { n.is_path_node = FALSE; n.think = SUB_Remove; n.nextthink = time; } entity pathlib_mknode(vector where,entity parent) { entity node; node = pathlib_nodeatpoint(where); if(node) { mark_error(where,60); return node; } node = spawn(); node.think = SUB_Remove; node.nextthink = time + PATHLIB_NODEEXPIRE; node.is_path_node = TRUE; node.owner = openlist; node.path_prev = parent; setmodel(node,"models/pathlib/square.md3"); setsize(node,'0 0 0','0 0 0'); node.colormod = randomvec() * 2; node.alpha = 0.25; node.scale = pathlib_gridsize / 512.001; //pathlib_showsquare2(node,'1 1 1',0);//(node.medium & CONTENT_EMPTY)); setorigin(node, where); node.medium = pointcontents(where); mark_info(where,60); //pathlib_showsquare(where,1,30); ++pathlib_made_cnt; ++pathlib_open_cnt; return node; } float pathlib_makenode_adaptive(entity parent,vector start, vector to, vector goal,float cost) { entity node; float h,g,f,doedge; vector where; ++pathlib_searched_cnt; if(inwater(parent.origin)) { pathlib_expandnode = pathlib_expandnode_box; pathlib_movenode = pathlib_swimnode; } else { if(inwater(to)) { pathlib_expandnode = pathlib_expandnode_box; pathlib_movenode = pathlib_walknode; } else { //if(edge_check(parent.origin)) // return 0; pathlib_expandnode = pathlib_expandnode_star; pathlib_movenode = pathlib_walknode; doedge = 1; } } node = pathlib_nodeatpoint(to); if(node) { ++pathlib_merge_cnt; if(node.owner == openlist) { h = pathlib_heuristic(node.origin,goal); g = pathlib_cost(parent,node.origin,cost); f = g + h; if(node.pathlib_node_g > g) { node.pathlib_node_h = h; node.pathlib_node_g = g; node.pathlib_node_f = f; node.path_prev = parent; } if not (best_open_node) best_open_node = node; else if(best_open_node.pathlib_node_f > node.pathlib_node_f) best_open_node = node; } return 1; } where = pathlib_movenode(parent.origin,to,0); if not(pathlib_movenode_goodnode) return 0; if(pathlib_nodeatpoint(where)) { dprint("NAP WHERE :",vtos(where),"\n"); dprint("not NAP TO:",vtos(to),"\n"); dprint("NAP-NNAP:",ftos(vlen(to-where)),"\n\n"); return 0; } if(doedge) if not (tile_check(where)) return 0; h = pathlib_heuristic(where,goal); g = pathlib_cost(parent,where,cost); f = g + h; /* node = findradius(where,pathlib_gridsize * 0.5); while(node) { if(node.is_path_node == TRUE) { ++pathlib_merge_cnt; if(node.owner == openlist) { if(node.pathlib_node_g > g) { //pathlib_movenode(where,node.origin,0); //if(pathlib_movenode_goodnode) //{ //mark_error(node.origin + '0 0 128',30); node.pathlib_node_h = h; node.pathlib_node_g = g; node.pathlib_node_f = f; node.path_prev = parent; //} } if not (best_open_node) best_open_node = node; else if(best_open_node.pathlib_node_f > node.pathlib_node_f) best_open_node = node; } return 1; } node = node.chain; } */ node = pathlib_mknode(where,parent); node.pathlib_node_h = h; node.pathlib_node_g = g; node.pathlib_node_f = f; if not (best_open_node) best_open_node = node; else if(best_open_node.pathlib_node_f > node.pathlib_node_f) best_open_node = node; return 1; } entity pathlib_getbestopen() { entity node; entity bestnode; if(best_open_node) { ++pathlib_bestcash_hits; pathlib_bestcash_saved += pathlib_open_cnt; return best_open_node; } node = findchainentity(owner,openlist); if(!node) return world; bestnode = node; while(node) { ++pathlib_bestopen_seached; if(node.pathlib_node_f < bestnode.pathlib_node_f) bestnode = node; node = node.chain; } return bestnode; } void pathlib_close_node(entity node,vector goal) { if(node.owner == closedlist) { dprint("Pathlib: Tried to close a closed node!\n"); return; } if(node == best_open_node) best_open_node = world; ++pathlib_closed_cnt; --pathlib_open_cnt; node.owner = closedlist; if(vlen(node.origin - goal) <= pathlib_gridsize) { vector goalmove; goalmove = pathlib_walknode(node.origin,goal,1); if(pathlib_movenode_goodnode) { goal_node = node; pathlib_foundgoal = TRUE; } } } void pathlib_cleanup() { best_open_node = world; //return; entity node; node = findfloat(world,is_path_node, TRUE); while(node) { /* node.owner = openlist; node.pathlib_node_g = 0; node.pathlib_node_h = 0; node.pathlib_node_f = 0; node.path_prev = world; */ dumpnode(node); node = findfloat(node,is_path_node, TRUE); } if(openlist) remove(openlist); if(closedlist) remove(closedlist); openlist = world; closedlist = world; } float Cosine_Interpolate(float a, float b, float x) { float ft,f; ft = x * 3.1415927; f = (1 - cos(ft)) * 0.5; return a*(1-f) + b*f; } float buildpath_nodefilter_directional(vector n,vector c,vector p) { vector d1,d2; d2 = normalize(p - c); d1 = normalize(c - n); if(vlen(d1-d2) < 0.25) { //mark_error(c,30); return 1; } //mark_info(c,30); return 0; } float buildpath_nodefilter_moveskip(vector n,vector c,vector p) { pathlib_walknode(p,n,1); if(pathlib_movenode_goodnode) return 1; return 0; } entity path_build(entity next, vector where, entity prev, entity start) { entity path; if(prev && next) if(buildpath_nodefilter) if(buildpath_nodefilter(next.origin,where,prev.origin)) return next; path = spawn(); path.owner = start; path.path_next = next; setorigin(path,where); if(!next) path.classname = "path_end"; else { if(!prev) path.classname = "path_start"; else path.classname = "path_node"; } return path; } entity pathlib_astar(vector from,vector to) { entity path, start, end, open, n, ln; float ptime, ftime, ctime; ptime = gettime(GETTIME_REALTIME); pathlib_starttime = ptime; pathlib_cleanup(); // Select water<->land capable node make/link pathlib_makenode = pathlib_makenode_adaptive; // Select XYZ cost estimate //pathlib_heuristic = pathlib_h_diagonal3; pathlib_heuristic = pathlib_h_diagonal; // Select distance + waterfactor cost pathlib_cost = pathlib_g_euclidean_water; // Select star expander pathlib_expandnode = pathlib_expandnode_star; // Select walk simulation movement test pathlib_movenode = pathlib_walknode; // Filter final nodes by direction buildpath_nodefilter = buildpath_nodefilter_directional; // Filter tiles with cross pattern tile_check = tile_check_cross; // If the start is in water we need diffrent settings if(inwater(from)) { // Select volumetric node expaner pathlib_expandnode = pathlib_expandnode_box; // Water movement test pathlib_movenode = pathlib_swimnode; } if not(openlist) openlist = spawn(); if not(closedlist) closedlist = spawn(); pathlib_closed_cnt = 0; pathlib_open_cnt = 0; pathlib_made_cnt = 0; pathlib_merge_cnt = 0; pathlib_searched_cnt = 0; pathlib_bestopen_seached = 0; pathlib_bestcash_hits = 0; pathlib_bestcash_saved = 0; pathlib_gridsize = 128; pathlib_movecost = pathlib_gridsize; pathlib_movecost_diag = vlen(('1 1 0' * pathlib_gridsize)); pathlib_movecost_waterfactor = 1; pathlib_foundgoal = 0; movenode_boxmax = self.maxs * 1.25; movenode_boxmin = self.mins * 1.25; movenode_stepsize = 32; tile_check_size = 65; tile_check_up = '0 0 128'; tile_check_down = '0 0 128'; movenode_stepup = '0 0 36'; movenode_maxdrop = '0 0 128'; movenode_boxup = '0 0 72'; from_x = fsnap(from_x,pathlib_gridsize); from_y = fsnap(from_y,pathlib_gridsize); to_x = fsnap(to_x,pathlib_gridsize); to_y = fsnap(to_y,pathlib_gridsize); dprint("AStar init\n"); path = pathlib_mknode(from,world); pathlib_close_node(path,to); if(pathlib_foundgoal) { dprint("AStar: Goal found on first node!\n"); open = spawn(); open.owner = open; open.classname = "path_end"; setorigin(open,path.origin); pathlib_cleanup(); return open; } if(pathlib_expandnode(path,from,to) <= 0) { dprint("AStar path fail.\n"); pathlib_cleanup(); return world; } best_open_node = pathlib_getbestopen(); n = best_open_node; pathlib_close_node(best_open_node,to); if(inwater(n.origin)) pathlib_expandnode_box(n,from,to); else pathlib_expandnode_star(n,from,to); while(pathlib_open_cnt) { if((gettime(GETTIME_REALTIME) - pathlib_starttime) > pathlib_maxtime) { dprint("Path took to long to compute!\n"); dprint("Nodes - created: ", ftos(pathlib_made_cnt),"\n"); dprint("Nodes - open: ", ftos(pathlib_open_cnt),"\n"); dprint("Nodes - merged: ", ftos(pathlib_merge_cnt),"\n"); dprint("Nodes - closed: ", ftos(pathlib_closed_cnt),"\n"); pathlib_cleanup(); return world; } best_open_node = pathlib_getbestopen(); n = best_open_node; pathlib_close_node(best_open_node,to); if(inwater(n.origin)) pathlib_expandnode_box(n,from,to); else pathlib_expandnode(n,from,to); if(pathlib_foundgoal) { dprint("Target found. Rebuilding and filtering path...\n"); ftime = gettime(GETTIME_REALTIME); ptime = ftime - ptime; start = path_build(world,path.origin,world,world); end = path_build(world,goal_node.origin,world,start); ln = end; open = goal_node; for(open = goal_node; open.path_prev != path; open = open.path_prev) { n = path_build(ln,open.origin,open.path_prev,start); ln.path_prev = n; ln = n; } start.path_next = n; n.path_prev = start; ftime = gettime(GETTIME_REALTIME) - ftime; ctime = gettime(GETTIME_REALTIME); pathlib_cleanup(); ctime = gettime(GETTIME_REALTIME) - ctime; #ifdef DEBUGPATHING pathlib_showpath2(start); dprint("Time used - pathfinding: ", ftos(ptime),"\n"); dprint("Time used - rebuild & filter: ", ftos(ftime),"\n"); dprint("Time used - cleanup: ", ftos(ctime),"\n"); dprint("Time used - total: ", ftos(ptime + ftime + ctime),"\n"); dprint("Time used - # frames: ", ftos(ceil((ptime + ftime + ctime) / sys_ticrate)),"\n\n"); dprint("Nodes - created: ", ftos(pathlib_made_cnt),"\n"); dprint("Nodes - open: ", ftos(pathlib_open_cnt),"\n"); dprint("Nodes - merged: ", ftos(pathlib_merge_cnt),"\n"); dprint("Nodes - closed: ", ftos(pathlib_closed_cnt),"\n"); dprint("Nodes - searched: ", ftos(pathlib_searched_cnt),"\n"); dprint("Nodes bestopen searched: ", ftos(pathlib_bestopen_seached),"\n"); dprint("Nodes bestcash - hits: ", ftos(pathlib_bestcash_hits),"\n"); dprint("Nodes bestcash - save: ", ftos(pathlib_bestcash_saved),"\n"); dprint("AStar done.\n"); #endif return start; } } dprint("A* Faild to find a path! Try a smaller gridsize.\n"); pathlib_cleanup(); return world; }