src/cmd/tpic/arcgen.c - plan9 - Git at Google

 #include	<stdio.h>
 #include	<math.h>
 #include	"pic.h"
 #include	"y.tab.h"

 obj*
 arcgen(int type)	/* handles circular and (eventually) elliptical arcs */
 {
 	static double prevw = HT10;
 	static double prevh = HT5;
 	static double prevrad = HT2;
 	static int dtox[2][4] ={ 1, -1, -1, 1, 1, 1, -1, -1 };
 	static int dtoy[2][4] ={ 1, 1, -1, -1, -1, 1, 1, -1 };
 	static int dctrx[2][4] ={ 0, -1, 0, 1, 0, 1, 0, -1 };
 	static int dctry[2][4] ={ 1, 0, -1, 0, -1, 0, 1, 0 };
 	static int nexthv[2][4] ={ U_DIR, L_DIR, D_DIR, R_DIR, D_DIR, R_DIR, U_DIR, L_DIR };
 	double dx2, dy2, ht, phi, r, d;
 	int i, head, to, at, cw, invis, ddtype;
 	obj *p, *ppos;
 	double fromx, fromy, tox, toy;
 	Attr *ap;

 	tox = 0;
 	toy = 0;
 	prevrad = getfval("arcrad");
 	prevh = getfval("arrowht");
 	prevw = getfval("arrowwid");
 	fromx = curx;
 	fromy = cury;
 	head = to = at = cw = invis = ddtype = 0;
 	for (i = 0; i < nattr; i++) {
 		ap = &attr[i];
 		switch (ap->a_type) {
 		case TEXTATTR:
 			savetext(ap->a_sub, ap->a_val.p);
 			break;
 		case HEAD:
 			head += ap->a_val.i;
 			break;
 		case INVIS:
 			invis = INVIS;
 			break;
 		case HEIGHT:	/* length of arrowhead */
 			prevh = ap->a_val.f;
 			break;
 		case WIDTH:	/* width of arrowhead */
 			prevw = ap->a_val.f;
 			break;
 		case RADIUS:
 			prevrad = ap->a_val.f;
 			break;
 		case DIAMETER:
 			prevrad = ap->a_val.f / 2;
 			break;
 		case CW:
 			cw = 1;
 			break;
 		case FROM:	/* start point of arc */
 			ppos = ap->a_val.o;
 			fromx = ppos->o_x;
 			fromy = ppos->o_y;
 			break;
 		case TO:	/* end point of arc */
 			ppos = ap->a_val.o;
 			tox = ppos->o_x;
 			toy = ppos->o_y;
 			to++;
 			break;
 		case AT:	/* center of arc */
 			ppos = ap->a_val.o;
 			curx = ppos->o_x;
 			cury = ppos->o_y;
 			at = 1;
 			break;
 		case UP:
 			hvmode = U_DIR;
 			break;
 		case DOWN:
 			hvmode = D_DIR;
 			break;
 		case RIGHT:
 			hvmode = R_DIR;
 			break;
 		case LEFT:
 			hvmode = L_DIR;
 			break;
 		}
 	}
 	if (!at && !to) {	/* the defaults are mostly OK */
 		curx = fromx + prevrad * dctrx[cw][hvmode];
 		cury = fromy + prevrad * dctry[cw][hvmode];
 		tox = fromx + prevrad * dtox[cw][hvmode];
 		toy = fromy + prevrad * dtoy[cw][hvmode];
 		hvmode = nexthv[cw][hvmode];
 	}
 	else if (!at) {
 		dx2 = (tox - fromx) / 2;
 		dy2 = (toy - fromy) / 2;
 		phi = atan2(dy2, dx2) + (cw ? -PI/2 : PI/2);
 		if (prevrad <= 0.0)
 			prevrad = dx2*dx2+dy2*dy2;
 		for (r=prevrad; (d = r*r - (dx2*dx2+dy2*dy2)) <= 0.0; r *= 2)
 			;	/* this kludge gets around too-small radii */
 		prevrad = r;
 		ht = sqrt(d);
 		curx = fromx + dx2 + ht * cos(phi);
 		cury = fromy + dy2 + ht * sin(phi);
 		dprintf("dx2,dy2=%g,%g, phi=%g, r,ht=%g,%g\n",
 			dx2, dy2, phi, r, ht);
 	}
 	else if (at && !to) {	/* do we have all the cases??? */
 		tox = fromx + prevrad * dtox[cw][hvmode];
 		toy = fromy + prevrad * dtoy[cw][hvmode];
 		hvmode = nexthv[cw][hvmode];
 	}
 	if (cw) {	/* interchange roles of from-to and heads */
 		double temp;
 		temp = fromx; fromx = tox; tox = temp;
 		temp = fromy; fromy = toy; toy = temp;
 		if (head == HEAD1)
 			head = HEAD2;
 		else if (head == HEAD2)
 			head = HEAD1;
 	}
 	p = makenode(type, 7);
 	arc_extreme(fromx, fromy, tox, toy, curx, cury);
 	p->o_val[0] = fromx;
 	p->o_val[1] = fromy;
 	p->o_val[2] = tox;
 	p->o_val[3] = toy;
 	if (cw) {
 		curx = fromx;
 		cury = fromy;
 	} else {
 		curx = tox;
 		cury = toy;
 	}
 	p->o_val[4] = prevw;
 	p->o_val[5] = prevh;
 	p->o_val[6] = prevrad;
 	p->o_attr = head | (cw ? CW_ARC : 0) | invis | ddtype;
 	if (head)
 		p->o_nhead = getfval("arrowhead");
 	dprintf("arc rad %g at %g %g from %g %g to %g %g head %g %g\n",
 		prevrad, p->o_x, p->o_y,
 		p->o_val[0], p->o_val[1], p->o_val[2], p->o_val[3], p->o_val[4], p->o_val[5]);
 	return(p);
 }

 /***************************************************************************
    bounding box of a circular arc             Eric Grosse  24 May 84

 Conceptually, this routine generates a list consisting of the start,
 end, and whichever north, east, south, and west points lie on the arc.
 The bounding box is then the range of this list.
     list = {start,end}
     j = quadrant(start)
     k = quadrant(end)
     if( j==k && long way 'round )  append north,west,south,east
     else
       while( j != k )
          append center+radius*[j-th of north,west,south,east unit vectors]
          j += 1  (mod 4)
     return( bounding box of list )
 The following code implements this, with simple optimizations.
 ***********************************************************************/


 void
 arc_extreme(double x0, double y0, double x1, double y1, double xc, double yc)
 {
 	/* assumes center isn't too far out */
 	double r, xmin, ymin, xmax, ymax;
 	int j, k;
 	x0 -= xc; y0 -= yc;	/* move to center */
 	x1 -= xc; y1 -= yc;
 	xmin = (x0<x1)?x0:x1; ymin = (y0<y1)?y0:y1;
 	xmax = (x0>x1)?x0:x1; ymax = (y0>y1)?y0:y1;
 	r = sqrt(x0*x0 + y0*y0);
 	if (r > 0.0) {
 		j = quadrant(x0,y0);
 		k = quadrant(x1,y1);
 		if (j == k && y1*x0 < x1*y0) {
 			/* viewed as complex numbers, if Im(z1/z0)<0, arc is big */
 			if( xmin > -r) xmin = -r; if( ymin > -r) ymin = -r;
 			if( xmax <  r) xmax =  r; if( ymax <  r) ymax =  r;
 		} else {
 			while (j != k) {
 				switch (j) {
 					case 1: if( ymax <  r) ymax =  r; break; /* north */
 					case 2: if( xmin > -r) xmin = -r; break; /* west */
 					case 3: if( ymin > -r) ymin = -r; break; /* south */
 					case 4: if( xmax <  r) xmax =  r; break; /* east */
 				}
 				j = j%4 + 1;
 			}
 		}
 	}
 	xmin += xc; ymin += yc;
 	xmax += xc; ymax += yc;
 	extreme(xmin, ymin);
 	extreme(xmax, ymax);
 }

 int
 quadrant(double x, double y)
 {
 	if (     x>=0.0 && y> 0.0) return(1);
 	else if( x< 0.0 && y>=0.0) return(2);
 	else if( x<=0.0 && y< 0.0) return(3);
 	else if( x> 0.0 && y<=0.0) return(4);
 	else			   return 0;	/* shut up lint */
 }
	#include <stdio.h>
	#include <math.h>
	#include "pic.h"
	#include "y.tab.h"

	obj*
	arcgen(int type) /* handles circular and (eventually) elliptical arcs */
	{
	static double prevw = HT10;
	static double prevh = HT5;
	static double prevrad = HT2;
	static int dtox[2][4] ={ 1, -1, -1, 1, 1, 1, -1, -1 };
	static int dtoy[2][4] ={ 1, 1, -1, -1, -1, 1, 1, -1 };
	static int dctrx[2][4] ={ 0, -1, 0, 1, 0, 1, 0, -1 };
	static int dctry[2][4] ={ 1, 0, -1, 0, -1, 0, 1, 0 };
	static int nexthv[2][4] ={ U_DIR, L_DIR, D_DIR, R_DIR, D_DIR, R_DIR, U_DIR, L_DIR };
	double dx2, dy2, ht, phi, r, d;
	int i, head, to, at, cw, invis, ddtype;
	obj p, ppos;
	double fromx, fromy, tox, toy;
	Attr *ap;

	tox = 0;
	toy = 0;
	prevrad = getfval("arcrad");
	prevh = getfval("arrowht");
	prevw = getfval("arrowwid");
	fromx = curx;
	fromy = cury;
	head = to = at = cw = invis = ddtype = 0;
	for (i = 0; i < nattr; i++) {
	ap = &attr[i];
	switch (ap->a_type) {
	case TEXTATTR:
	savetext(ap->a_sub, ap->a_val.p);
	break;
	case HEAD:
	head += ap->a_val.i;
	break;
	case INVIS:
	invis = INVIS;
	break;
	case HEIGHT: /* length of arrowhead */
	prevh = ap->a_val.f;
	break;
	case WIDTH: /* width of arrowhead */
	prevw = ap->a_val.f;
	break;
	case RADIUS:
	prevrad = ap->a_val.f;
	break;
	case DIAMETER:
	prevrad = ap->a_val.f / 2;
	break;
	case CW:
	cw = 1;
	break;
	case FROM: /* start point of arc */
	ppos = ap->a_val.o;
	fromx = ppos->o_x;
	fromy = ppos->o_y;
	break;
	case TO: /* end point of arc */
	ppos = ap->a_val.o;
	tox = ppos->o_x;
	toy = ppos->o_y;
	to++;
	break;
	case AT: /* center of arc */
	ppos = ap->a_val.o;
	curx = ppos->o_x;
	cury = ppos->o_y;
	at = 1;
	break;
	case UP:
	hvmode = U_DIR;
	break;
	case DOWN:
	hvmode = D_DIR;
	break;
	case RIGHT:
	hvmode = R_DIR;
	break;
	case LEFT:
	hvmode = L_DIR;
	break;
	}
	}
	if (!at && !to) { /* the defaults are mostly OK */
	curx = fromx + prevrad * dctrx[cw][hvmode];
	cury = fromy + prevrad * dctry[cw][hvmode];
	tox = fromx + prevrad * dtox[cw][hvmode];
	toy = fromy + prevrad * dtoy[cw][hvmode];
	hvmode = nexthv[cw][hvmode];
	}
	else if (!at) {
	dx2 = (tox - fromx) / 2;
	dy2 = (toy - fromy) / 2;
	phi = atan2(dy2, dx2) + (cw ? -PI/2 : PI/2);
	if (prevrad <= 0.0)
	prevrad = dx2dx2+dy2dy2;
	for (r=prevrad; (d = rr - (dx2dx2+dy2dy2)) <= 0.0; r = 2)
	; /* this kludge gets around too-small radii */
	prevrad = r;
	ht = sqrt(d);
	curx = fromx + dx2 + ht * cos(phi);
	cury = fromy + dy2 + ht * sin(phi);
	dprintf("dx2,dy2=%g,%g, phi=%g, r,ht=%g,%g\n",
	dx2, dy2, phi, r, ht);
	}
	else if (at && !to) { /* do we have all the cases??? */
	tox = fromx + prevrad * dtox[cw][hvmode];
	toy = fromy + prevrad * dtoy[cw][hvmode];
	hvmode = nexthv[cw][hvmode];
	}
	if (cw) { /* interchange roles of from-to and heads */
	double temp;
	temp = fromx; fromx = tox; tox = temp;
	temp = fromy; fromy = toy; toy = temp;
	if (head == HEAD1)
	head = HEAD2;
	else if (head == HEAD2)
	head = HEAD1;
	}
	p = makenode(type, 7);
	arc_extreme(fromx, fromy, tox, toy, curx, cury);
	p->o_val[0] = fromx;
	p->o_val[1] = fromy;
	p->o_val[2] = tox;
	p->o_val[3] = toy;
	if (cw) {
	curx = fromx;
	cury = fromy;
	} else {
	curx = tox;
	cury = toy;
	}
	p->o_val[4] = prevw;
	p->o_val[5] = prevh;
	p->o_val[6] = prevrad;
	p->o_attr = head \| (cw ? CW_ARC : 0) \| invis \| ddtype;
	if (head)
	p->o_nhead = getfval("arrowhead");
	dprintf("arc rad %g at %g %g from %g %g to %g %g head %g %g\n",
	prevrad, p->o_x, p->o_y,
	p->o_val[0], p->o_val[1], p->o_val[2], p->o_val[3], p->o_val[4], p->o_val[5]);
	return(p);
	}

	/***************************************************************************
	bounding box of a circular arc Eric Grosse 24 May 84

	Conceptually, this routine generates a list consisting of the start,
	end, and whichever north, east, south, and west points lie on the arc.
	The bounding box is then the range of this list.
	list = {start,end}
	j = quadrant(start)
	k = quadrant(end)
	if( j==k && long way 'round ) append north,west,south,east
	else
	while( j != k )
	append center+radius*[j-th of north,west,south,east unit vectors]
	j += 1 (mod 4)
	return( bounding box of list )
	The following code implements this, with simple optimizations.
	***********************************************************************/


	void
	arc_extreme(double x0, double y0, double x1, double y1, double xc, double yc)
	{
	/* assumes center isn't too far out */
	double r, xmin, ymin, xmax, ymax;
	int j, k;
	x0 -= xc; y0 -= yc; /* move to center */
	x1 -= xc; y1 -= yc;
	xmin = (x0<x1)?x0:x1; ymin = (y0<y1)?y0:y1;
	xmax = (x0>x1)?x0:x1; ymax = (y0>y1)?y0:y1;
	r = sqrt(x0x0 + y0y0);
	if (r > 0.0) {
	j = quadrant(x0,y0);
	k = quadrant(x1,y1);
	if (j == k && y1x0 < x1y0) {
	/* viewed as complex numbers, if Im(z1/z0)<0, arc is big */
	if( xmin > -r) xmin = -r; if( ymin > -r) ymin = -r;
	if( xmax < r) xmax = r; if( ymax < r) ymax = r;
	} else {
	while (j != k) {
	switch (j) {
	case 1: if( ymax < r) ymax = r; break; /* north */
	case 2: if( xmin > -r) xmin = -r; break; /* west */
	case 3: if( ymin > -r) ymin = -r; break; /* south */
	case 4: if( xmax < r) xmax = r; break; /* east */
	}
	j = j%4 + 1;
	}
	}
	}
	xmin += xc; ymin += yc;
	xmax += xc; ymax += yc;
	extreme(xmin, ymin);
	extreme(xmax, ymax);
	}

	int
	quadrant(double x, double y)
	{
	if ( x>=0.0 && y> 0.0) return(1);
	else if( x< 0.0 && y>=0.0) return(2);
	else if( x<=0.0 && y< 0.0) return(3);
	else if( x> 0.0 && y<=0.0) return(4);
	else return 0; /* shut up lint */
	}