ref: 596459dd77e5c3e66a57be31e711a58624024881
dir: /a∗.c/
#include <u.h> #include <libc.h> #include <draw.h> #include "dat.h" #include "fns.h" static Pairheap *queue; static Node *nearest; static void clearpath(void) { nukequeue(&queue); memset(map, 0, mapwidth * mapheight * sizeof *map); nearest = nil; } static Node * a∗nearestfree(Node*, Node*, Node *nearest) { return nearest; } void a∗backtrack(Mobj *mo, Node *b, Node *a) { Path *pp; pp = &mo->path; assert(b != a && b->step > 0); pp->dist = b->len; clearvec(&pp->moves); for(; b!=a; b=b->from){ assert(b != nil); dprint("%M a∗: backtracking: %#p %P dist %f from %#p\n", mo, b, b->Point, b->h, b->from); pushvec(&pp->moves, &b->Point); } pp->step = (Point *)pp->moves.p + pp->moves.n - 1; } static Node ** a∗successors(Mobj *mo, Node *n, Node*) { static Node *dir[8+1]; static dtab[2*(nelem(dir)-1)]={ -1,-1, 0,-1, 1,-1, -1,0, 1,0, -1,1, 0,1, 1,1, }; int i; Node *s, **p; memset(dir, 0, sizeof dir); for(i=0, p=dir; i<nelem(dtab); i+=2){ s = n + dtab[i+1] * mapwidth + dtab[i]; if(s >= map && s < map + mapwidth * mapheight){ s->Point = addpt(n->Point, Pt(dtab[i], dtab[i+1])); if(isblocked(s->Point, mo->o)) continue; s->Δg = 1; s->Δlen = dtab[i] != 0 && dtab[i+1] != 0 ? SQRT2 : 1; // UGHHHHh s->x = (s - map) % mapwidth; s->y = (s - map) / mapwidth; *p++ = s; } } return dir; } Node * a∗(Mobj *mo, Node *a, Node *b, Node**(*successorsfn)(Mobj*,Node*,Node*)) { double g, Δg; Node *x, *n, **dp; Pairheap *pn; if(a == b){ werrstr("a∗: moving in place"); return nil; } clearpath(); a->Point = mo->Point; b->Point = Pt((b-map)%mapwidth, (b-map)/mapwidth); x = a; a->h = octdist(a->Point, b->Point); pushqueue(a, &queue); while((pn = popqueue(&queue)) != nil){ x = pn->n; free(pn); if(x == b) break; x->closed = 1; dp = successorsfn(mo, x, b); for(n=*dp++; n!=nil; n=*dp++){ if(n->closed) continue; if(isblocked(n->Point, mo->o)) continue; g = x->g + n->Δg; Δg = n->g - g; if(!n->open){ n->from = x; n->open = 1; n->step = x->step + 1; n->h = octdist(n->Point, b->Point); n->len = x->len + n->Δlen; n->g = g; pushqueue(n, &queue); }else if(Δg > 0){ n->from = x; n->step = x->step + 1; n->len = x->len + n->Δlen; n->g -= Δg; decreasekey(n->p, Δg, &queue); assert(n->g >= 0); } if(nearest == nil || n->h < nearest->h){ nearest = n; dprint("%M a∗: nearest node now %#p %P dist %f\n", mo, n, n->Point, n->h); } } } return x; } Node * a∗findpath(Mobj *mo, Node *a, Node *b) { Node *n, *m; if(a∗(mo, a, b, jpsbsuccessors) == b){ dprint("%M a∗path: successfully found %#p at %P dist %f\n", mo, b, b->Point, b->h); return b; } dprint("%M a∗findpath: goal unreachable\n", mo); n = nearest; if(n == a || n == nil){ werrstr("a∗findpath: can't move"); return nil; } dprint("%M findpath: nearest jump is %#p %P dist %f\n", mo, n, n->Point, n->h); m = jpsbnearestnonjump(mo, n, b); if(nearest == nil || nearest == n){ dprint("%M a∗findpath: failed to find nearer non-jump point\n", mo); nearest = n; } if(m == b){ dprint("%M a∗findpath: jps pathfinding failed but plain a∗ found the goal\n", mo); nearest = b; } /* m( */ m = a∗(mo, a, nearest, a∗successors); return m == b ? b : nearest; }