Plan 9 from Bell Labs’s /usr/web/sources/contrib/steve/root/sys/src/cmd/graphviz/pathplan/shortest.c

Copyright © 2021 Plan 9 Foundation.
Distributed under the MIT License.
Download the Plan 9 distribution.


/*
    This software may only be used by you under license from AT&T Corp.
    ("AT&T").  A copy of AT&T's Source Code Agreement is available at
    AT&T's Internet website having the URL:
    <http://www.research.att.com/sw/tools/graphviz/license/source.html>
    If you received this software without first entering into a license
    with AT&T, you have an infringing copy of this software and cannot use
    it without violating AT&T's intellectual property rights.
*/
#pragma prototyped

#include <stdlib.h>
#include <stdio.h>
#ifdef HAVE_MALLOC_H
#include <malloc.h>
#endif
#include <limits.h>
#include <math.h>
#include "pathplan.h"

#ifdef DMALLOC
#include "dmalloc.h"
#endif

#define ISCCW 1
#define ISCW  2
#define ISON  3

#define DQ_FRONT 1
#define DQ_BACK  2

#ifndef TRUE
#define TRUE 1
#define FALSE 0
#endif

#define prerror(msg) \
        fprintf (stderr, "libpath/%s:%d: %s\n", __FILE__, __LINE__, (msg))

#define POINTSIZE sizeof (Ppoint_t)

typedef struct pointnlink_t {
    Ppoint_t *pp;
    struct pointnlink_t *link;
} pointnlink_t;

#define POINTNLINKSIZE sizeof (pointnlink_t)
#define POINTNLINKPSIZE sizeof (pointnlink_t *)

typedef struct tedge_t {
    pointnlink_t *pnl0p;
    pointnlink_t *pnl1p;
    struct triangle_t *ltp;
    struct triangle_t *rtp;
} tedge_t;

typedef struct triangle_t {
    int mark;
    struct tedge_t e[3];
} triangle_t;

#define TRIANGLESIZE sizeof (triangle_t)

typedef struct deque_t {
    pointnlink_t **pnlps;
    int pnlpn, fpnlpi, lpnlpi, apex;
} deque_t;

static pointnlink_t *pnls, **pnlps;
static int pnln, pnll;

static triangle_t *tris;
static int trin, tril;

static deque_t dq;

static Ppoint_t *ops;
static int opn;

static void triangulate (pointnlink_t **, int);
static int isdiagonal (int, int, pointnlink_t **, int);
static void loadtriangle (pointnlink_t *, pointnlink_t *, pointnlink_t *);
static void connecttris (int, int);
static int marktripath (int, int);

static void add2dq (int, pointnlink_t *);
static void splitdq (int, int);
static int finddqsplit (pointnlink_t *);

static int ccw (Ppoint_t *, Ppoint_t *, Ppoint_t *);
static int intersects (Ppoint_t *, Ppoint_t *, Ppoint_t *, Ppoint_t *);
static int between (Ppoint_t *, Ppoint_t *, Ppoint_t *);
static int pointintri (int, Ppoint_t *);

static void growpnls (int);
static void growtris (int);
static void growdq (int);
static void growops (int);

int Pshortestpath (Ppoly_t *polyp, Ppoint_t *eps, Ppolyline_t *output) {
    int pi, minpi;
    double minx;
    Ppoint_t p1, p2, p3;
    int trii, trij, ftrii, ltrii;
    int ei;
    pointnlink_t epnls[2], *lpnlp, *rpnlp, *pnlp;
    triangle_t *trip;
    int splitindex;
#ifdef DEBUG
    int pnli;
#endif

    /* make space */
    growpnls (polyp->pn);
    pnll = 0;
    tril = 0;
    growdq (polyp->pn * 2);
    dq.fpnlpi = dq.pnlpn / 2, dq.lpnlpi = dq.fpnlpi - 1;

    /* make sure polygon is CCW and load pnls array */
    for (pi = 0, minx = HUGE_VAL, minpi = -1; pi < polyp->pn; pi++) {
        if (minx > polyp->ps[pi].x)
            minx = polyp->ps[pi].x, minpi = pi;
    }
    p2 = polyp->ps[minpi];
    p1 = polyp->ps[((minpi == 0) ? polyp->pn - 1: minpi - 1)];
    p3 = polyp->ps[((minpi == polyp->pn - 1) ? 0 : minpi + 1)];
    if (((p1.x == p2.x && p2.x == p3.x) && (p3.y > p2.y)) ||
            ccw (&p1, &p2, &p3) != ISCCW) {
        for (pi = polyp->pn - 1; pi >= 0; pi--) {
            if (pi < polyp->pn - 1 && polyp->ps[pi].x == polyp->ps[pi + 1].x &&
                    polyp->ps[pi].y == polyp->ps[pi + 1].y)
                continue;
            pnls[pnll].pp = &polyp->ps[pi];
            pnls[pnll].link = &pnls[pnll % polyp->pn];
            pnlps[pnll] = &pnls[pnll];
            pnll++;
        }
    } else {
        for (pi = 0; pi < polyp->pn; pi++) {
            if (pi > 0 && polyp->ps[pi].x == polyp->ps[pi - 1].x &&
                    polyp->ps[pi].y == polyp->ps[pi - 1].y)
                continue;
            pnls[pnll].pp = &polyp->ps[pi];
            pnls[pnll].link = &pnls[pnll % polyp->pn];
            pnlps[pnll] = &pnls[pnll];
            pnll++;
        }
    }

#if DEBUG >= 1
    fprintf (stderr, "points\n%d\n", pnll);
    for (pnli = 0; pnli < pnll; pnli++)
        fprintf (stderr, "%f %f\n", pnls[pnli].pp->x, pnls[pnli].pp->y);
#endif

    /* generate list of triangles */
    triangulate (pnlps, pnll);

#if DEBUG >= 2
    fprintf (stderr, "triangles\n%d\n", tril);
    for (trii = 0; trii < tril; trii++)
        for (ei = 0; ei < 3; ei++)
            fprintf (stderr, "%f %f\n", tris[trii].e[ei].pnl0p->pp->x,
                    tris[trii].e[ei].pnl0p->pp->y);
#endif

    /* connect all pairs of triangles that share an edge */
    for (trii = 0; trii < tril; trii++)
        for (trij = trii + 1; trij < tril; trij++)
            connecttris (trii, trij);

    /* find first and last triangles */
    for (trii = 0; trii < tril; trii++)
        if (pointintri (trii, &eps[0]))
            break;
    if (trii == tril) {
        prerror ("source point not in any triangle");
        return -1;
    }
    ftrii = trii;
    for (trii = 0; trii < tril; trii++)
        if (pointintri (trii, &eps[1]))
            break;
    if (trii == tril) {
        prerror ("destination point not in any triangle");
        return -1;
    }
    ltrii = trii;

    /* mark the strip of triangles from eps[0] to eps[1] */
    if (!marktripath (ftrii, ltrii)) {
        prerror ("cannot find triangle path");
        abort ();
    }

    /* if endpoints in same triangle, use a single line */
    if (ftrii == ltrii) {
        growops (2);
		output->pn = 2;
        ops[0] = eps[0], ops[1] = eps[1];
		output->ps = ops;
        return 0;
    }

    /* build funnel and shortest path linked list (in add2dq) */
    epnls[0].pp = &eps[0], epnls[0].link = NULL;
    epnls[1].pp = &eps[1], epnls[1].link = NULL;
    add2dq (DQ_FRONT, &epnls[0]);
    dq.apex = dq.fpnlpi;
    trii = ftrii;
    while (trii != -1) {
        trip = &tris[trii];
        trip->mark = 2;

        /* find the left and right points of the exiting edge */
        for (ei = 0; ei < 3; ei++)
            if (trip->e[ei].rtp && trip->e[ei].rtp->mark == 1)
                break;
        if (ei == 3) { /* in last triangle */
            if (ccw (&eps[1], dq.pnlps[dq.fpnlpi]->pp,
                    dq.pnlps[dq.lpnlpi]->pp) == ISCCW)
                lpnlp = dq.pnlps[dq.lpnlpi], rpnlp = &epnls[1];
            else
                lpnlp = &epnls[1], rpnlp = dq.pnlps[dq.lpnlpi];
        } else {
            pnlp = trip->e[(ei + 1) % 3].pnl1p;
            if (ccw (trip->e[ei].pnl0p->pp, pnlp->pp,
                    trip->e[ei].pnl1p->pp) == ISCCW)
                lpnlp = trip->e[ei].pnl1p, rpnlp = trip->e[ei].pnl0p;
            else
                lpnlp = trip->e[ei].pnl0p, rpnlp = trip->e[ei].pnl1p;
        }

        /* update deque */
        if (trii == ftrii) {
            add2dq (DQ_BACK, lpnlp);
            add2dq (DQ_FRONT, rpnlp);
        } else {
            if (dq.pnlps[dq.fpnlpi] != rpnlp && dq.pnlps[dq.lpnlpi] != rpnlp) {
                /* add right point to deque */
                splitindex = finddqsplit (rpnlp);
                splitdq (DQ_BACK, splitindex);
                add2dq (DQ_FRONT, rpnlp);
                /* if the split is behind the apex, then reset apex */
                if (splitindex > dq.apex)
                    dq.apex = splitindex;
            } else {
                /* add left point to deque */
                splitindex = finddqsplit (lpnlp);
                splitdq (DQ_FRONT, splitindex);
                add2dq (DQ_BACK, lpnlp);
                /* if the split is in front of the apex, then reset apex */
                if (splitindex < dq.apex)
                    dq.apex = splitindex;
            }
        }
        trii = -1;
        for (ei = 0; ei < 3; ei++)
            if (trip->e[ei].rtp && trip->e[ei].rtp->mark == 1) {
                trii = trip->e[ei].rtp - tris;
                break;
            }
    }

#if DEBUG >= 1
    fprintf (stderr, "polypath");
    for (pnlp = &epnls[1]; pnlp; pnlp = pnlp->link)
        fprintf (stderr, " %f %f", pnlp->pp->x, pnlp->pp->y);
    fprintf (stderr, "\n");
#endif

    for (pi = 0, pnlp = &epnls[1]; pnlp; pnlp = pnlp->link)
        pi++;
    growops (pi);
	output->pn = pi;
    for (pi = pi - 1, pnlp = &epnls[1]; pnlp; pi--, pnlp = pnlp->link)
        ops[pi] = *pnlp->pp;
	output->ps = ops;

    return 0;
}

/* triangulate polygon */
static void triangulate (pointnlink_t **pnlps, int pnln) {
    int pnli, pnlip1, pnlip2;

    if (pnln > 3) {
        for (pnli = 0; pnli < pnln; pnli++) {
            pnlip1 = (pnli + 1) % pnln;
            pnlip2 = (pnli + 2) % pnln;
            if (isdiagonal (pnli, pnlip2, pnlps, pnln)) {
                loadtriangle (pnlps[pnli], pnlps[pnlip1], pnlps[pnlip2]);
                for (pnli = pnlip1; pnli < pnln - 1; pnli++)
                    pnlps[pnli] = pnlps[pnli + 1];
                triangulate (pnlps, pnln - 1);
                return;
            }
        }
        abort ();
    } else
        loadtriangle (pnlps[0], pnlps[1], pnlps[2]);
}

/* check if (i, i + 2) is a diagonal */
static int isdiagonal (int pnli, int pnlip2, pointnlink_t **pnlps, int pnln) {
    int pnlip1, pnlim1, pnlj, pnljp1, res;

    /* neighborhood test */
    pnlip1 = (pnli + 1) % pnln;
    pnlim1 = (pnli + pnln - 1) % pnln;
    /* If P[pnli] is a convex vertex [ pnli+1 left of (pnli-1,pnli) ]. */
    if (ccw (pnlps[pnlim1]->pp, pnlps[pnli]->pp, pnlps[pnlip1]->pp) == ISCCW)
        res = (ccw (pnlps[pnli]->pp, pnlps[pnlip2]->pp,
                pnlps[pnlim1]->pp) == ISCCW) &&
                (ccw (pnlps[pnlip2]->pp, pnlps[pnli]->pp,
                pnlps[pnlip1]->pp) == ISCCW);
    /* Assume (pnli - 1, pnli, pnli + 1) not collinear. */
    else
        res = (ccw (pnlps[pnli]->pp, pnlps[pnlip2]->pp,
                pnlps[pnlip1]->pp) == ISCW);
    if (!res)
        return FALSE;

    /* check against all other edges */
    for (pnlj = 0; pnlj < pnln; pnlj++) {
        pnljp1 = (pnlj + 1) % pnln;
        if (!((pnlj == pnli) || (pnljp1 == pnli) ||
                (pnlj == pnlip2) || (pnljp1 == pnlip2)))
            if (intersects (pnlps[pnli]->pp, pnlps[pnlip2]->pp,
                    pnlps[pnlj]->pp, pnlps[pnljp1]->pp))
                return FALSE;
    }
    return TRUE;
}

static void loadtriangle (pointnlink_t *pnlap, pointnlink_t *pnlbp,
        pointnlink_t *pnlcp) {
    triangle_t *trip;
    int ei;

    /* make space */
    if (tril >= trin)
        growtris (trin + 20);
    trip = &tris[tril++];
    trip->mark = 0;
    trip->e[0].pnl0p = pnlap, trip->e[0].pnl1p = pnlbp, trip->e[0].rtp = NULL;
    trip->e[1].pnl0p = pnlbp, trip->e[1].pnl1p = pnlcp, trip->e[1].rtp = NULL;
    trip->e[2].pnl0p = pnlcp, trip->e[2].pnl1p = pnlap, trip->e[2].rtp = NULL;
    for (ei = 0; ei < 3; ei++)
        trip->e[ei].ltp = trip;
}

/* connect a pair of triangles at their common edge (if any) */
static void connecttris (int tri1, int tri2) {
    triangle_t *tri1p, *tri2p;
    int ei, ej;

    for (ei = 0 ; ei < 3; ei++) {
        for (ej = 0; ej < 3; ej++) {
            tri1p = &tris[tri1], tri2p = &tris[tri2];
            if ((tri1p->e[ei].pnl0p->pp == tri2p->e[ej].pnl0p->pp &&
                    tri1p->e[ei].pnl1p->pp == tri2p->e[ej].pnl1p->pp) ||
                    (tri1p->e[ei].pnl0p->pp == tri2p->e[ej].pnl1p->pp &&
                    tri1p->e[ei].pnl1p->pp == tri2p->e[ej].pnl0p->pp))
                tri1p->e[ei].rtp = tri2p, tri2p->e[ej].rtp = tri1p;
        }
    }
}

/* find and mark path from trii, to trij */
static int marktripath (int trii, int trij) {
    int ei;

    if (tris[trii].mark)
        return FALSE;
    tris[trii].mark = 1;
    if (trii == trij)
        return TRUE;
    for (ei = 0; ei < 3; ei++)
        if (tris[trii].e[ei].rtp &&
                marktripath (tris[trii].e[ei].rtp - tris, trij))
            return TRUE;
    tris[trii].mark = 0;
    return FALSE;
}

/* add a new point to the deque, either front or back */
static void add2dq (int side, pointnlink_t *pnlp) {
    if (side == DQ_FRONT) {
        if (dq.lpnlpi - dq.fpnlpi >= 0)
            pnlp->link = dq.pnlps[dq.fpnlpi]; /* shortest path links */
        dq.fpnlpi--;
        dq.pnlps[dq.fpnlpi] = pnlp;
    } else {
        if (dq.lpnlpi - dq.fpnlpi >= 0)
            pnlp->link = dq.pnlps[dq.lpnlpi]; /* shortest path links */
        dq.lpnlpi++;
        dq.pnlps[dq.lpnlpi] = pnlp;
    }
}

static void splitdq (int side, int index) {
    if (side == DQ_FRONT)
        dq.lpnlpi = index;
    else
        dq.fpnlpi = index;
}

static int finddqsplit (pointnlink_t *pnlp) {
    int index;

    for (index = dq.fpnlpi; index < dq.apex; index++)
        if (ccw (dq.pnlps[index + 1]->pp, dq.pnlps[index]->pp, pnlp->pp) == ISCCW)
            return index;
    for (index = dq.lpnlpi; index > dq.apex; index--)
        if (ccw (dq.pnlps[index - 1]->pp, dq.pnlps[index]->pp, pnlp->pp) == ISCW)
            return index;
    return dq.apex;
}

/* ccw test: CCW, CW, or co-linear */
static int ccw (Ppoint_t *p1p, Ppoint_t *p2p, Ppoint_t *p3p) {
    double d;

    d = ((p1p->y - p2p->y) * (p3p->x - p2p->x)) -
            ((p3p->y - p2p->y) * (p1p->x - p2p->x));
    return (d > 0) ? ISCCW : ((d < 0) ? ISCW : ISON);
}

/* line to line intersection */
static int intersects (Ppoint_t *pap, Ppoint_t *pbp,
        Ppoint_t *pcp, Ppoint_t *pdp) {
    int ccw1, ccw2, ccw3, ccw4;

    if (ccw (pap, pbp, pcp) == ISON || ccw (pap, pbp, pdp) == ISON ||
            ccw (pcp, pdp, pap) == ISON || ccw (pcp, pdp, pbp) == ISON) {
        if (between (pap, pbp, pcp) || between (pap, pbp, pdp) ||
                between (pcp, pdp, pap) || between (pcp, pdp, pbp))
            return TRUE;
    } else {
        ccw1 = (ccw (pap, pbp, pcp) == ISCCW) ? 1 : 0;
        ccw2 = (ccw (pap, pbp, pdp) == ISCCW) ? 1 : 0;
        ccw3 = (ccw (pcp, pdp, pap) == ISCCW) ? 1 : 0;
        ccw4 = (ccw (pcp, pdp, pbp) == ISCCW) ? 1 : 0;
        return (ccw1 ^ ccw2) && (ccw3 ^ ccw4);
    }
    return FALSE;
}

/* is pbp between pap and pcp */
static int between (Ppoint_t *pap, Ppoint_t *pbp, Ppoint_t *pcp) {
    Ppoint_t p1, p2;

    p1.x = pbp->x - pap->x, p1.y = pbp->y - pap->y;
    p2.x = pcp->x - pap->x, p2.y = pcp->y - pap->y;
    if (ccw (pap, pbp, pcp) != ISON)
        return FALSE;
    return (p2.x * p1.x + p2.y * p1.y >= 0) &&
            (p2.x * p2.x + p2.y * p2.y <= p1.x * p1.x + p1.y * p1.y);
}

static int pointintri (int trii, Ppoint_t *pp) {
    int ei, sum;

    for (ei = 0, sum = 0; ei < 3; ei++)
        if (ccw (tris[trii].e[ei].pnl0p->pp,
                tris[trii].e[ei].pnl1p->pp, pp) != ISCW)
            sum++;
    return (sum == 3 || sum == 0);
}

static void growpnls (int newpnln) {
    if (newpnln <= pnln)
        return;
    if (!pnls) {
        if (!(pnls = (pointnlink_t *) malloc (POINTNLINKSIZE * newpnln))) {
            prerror ("cannot malloc pnls");
            abort ();
        }
        if (!(pnlps = (pointnlink_t **) malloc (POINTNLINKPSIZE * newpnln))) {
            prerror ("cannot malloc pnlps");
            abort ();
        }
    } else {
        if (!(pnls = (pointnlink_t *) realloc ((void *) pnls,
                POINTNLINKSIZE * newpnln))) {
            prerror ("cannot realloc pnls");
            abort ();
        }
        if (!(pnlps = (pointnlink_t **) realloc ((void *) pnlps,
                POINTNLINKPSIZE * newpnln))) {
            prerror ("cannot realloc pnlps");
            abort ();
        }
    }
    pnln = newpnln;
}

static void growtris (int newtrin) {
    if (newtrin <= trin)
        return;
    if (!tris) {
        if (!(tris = (triangle_t *) malloc (TRIANGLESIZE * newtrin))) {
            prerror ("cannot malloc tris");
            abort ();
        }
    } else {
        if (!(tris = (triangle_t *) realloc ((void *) tris,
                TRIANGLESIZE * newtrin))) {
            prerror ("cannot realloc tris");
            abort ();
        }
    }
    trin = newtrin;
}

static void growdq (int newdqn) {
    if (newdqn <= dq.pnlpn)
        return;
    if (!dq.pnlps) {
        if (!(dq.pnlps = (pointnlink_t **) malloc (POINTNLINKPSIZE * newdqn))) {
            prerror ("cannot malloc dq.pnls");
            abort ();
        }
    } else {
        if (!(dq.pnlps = (pointnlink_t **) realloc ((void *) dq.pnlps,
                POINTNLINKPSIZE * newdqn))) {
            prerror ("cannot realloc dq.pnls");
            abort ();
        }
    }
    dq.pnlpn = newdqn;
}

static void growops (int newopn) {
    if (newopn <= opn)
        return;
    if (!ops) {
        if (!(ops = (Ppoint_t *) malloc (POINTSIZE * newopn))) {
            prerror ("cannot malloc ops");
            abort ();
        }
    } else {
        if (!(ops = (Ppoint_t *) realloc ((void *) ops,
                POINTSIZE * newopn))) {
            prerror ("cannot realloc ops");
            abort ();
        }
    }
    opn = newopn;
}

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