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Length: 20332 (0x4f6c)
Types: TextFile
Names: »genlatex.c«
└─⟦52210d11f⟧ Bits:30007239 EUUGD2: TeX 3 1992-12
└─⟦c319c2751⟧ »unix3.0/TeX3.0.tar.Z«
└─⟦036c765ac⟧
└─⟦this⟧ »TeX3.0/TeXgraphics/transfig/fig2dev/dev/genlatex.c«
/*
* genlatex.c : LaTeX driver for fig2dev
*
* Author: Frank Schmuck, Cornell University 6/88
* Converted from fig2latex 5/89 by Micah Beck
*
*/
#ifdef hpux
#include <sys/types.h>
#endif
#include <sys/file.h>
#include <stdio.h>
#include <math.h>
#include "object.h"
#include "fig2dev.h"
#include "texfonts.h"
extern char *strchr();
extern void printf(), fprintf();
extern double rad2deg, sin(), cos(), acos(), fabs(), atan();
#ifdef hpux
#define rint(a) floor((a)+0.5) /* close enough? */
#endif
#ifdef gould
#define rint(a) floor((a)+0.5) /* close enough? */
#endif
/*
* Installation dependent constants:
*
* THINDOT latex command for generating a dot if line width = \thinlines
* THICKDOT latex command for generating a dot if line width = \thicklines
* MIN_LEN shortest slanted line that latex can produce; shorter lines will
* we translated into a sequence of dots generated by \multiput.
* THICK_LDOT latex command for generating the dot for making short slanted
* lines if line width = \thinlines
* THIN_LDOT ... if line width = \thicklines
*/
#define THICKDOT "\\tenrm ."
#define THINDOT "\\sevrm ."
double THIN_XOFF = (0.1/72.0);
double THIN_YOFF = (0.7/72.0);
double THICK_XOFF = (0.4/72.0);
double THICK_YOFF = (0.6/72.0);
#define THICK_LDOT "\\sevrm ."
#define THIN_LDOT "\\fivrm ."
double THIN_LXOFF = (0.1/72.0);
double THIN_LYOFF = (0.7/72.0);
double THICK_LXOFF = (0.4/72.0);
double THICK_LYOFF = (0.6/72.0);
#define MIN_LEN (13.0/72.0) /* 13 points */
/*
* other constants and macros
*/
#define TOP 840
#define THINLINES 1
#define THICKLINES 2
/*
* Cornell DVI-to-IP has trouble with circles of radius greater than 8pt.
*/
#ifdef CORNELL
#define MAXCIRCLEDIA 16
#else
#define MAXCIRCLEDIA 80
#endif
#define MAXCIRCLERAD ((MAXCIRCLEDIA-0.5)/(2*72.27))
#define SWAP(x,y) {tmp=x; x=y; y=tmp;}
#define TRANS(x,y) (*translate_coordinates)(&x,&y)
#define TRANS2(x1,y1,x2,y2) (*translate_coordinates)(&x1,&y1); \
(*translate_coordinates)(&x2,&y2)
#define TRANSD(x,y) (*translate_coordinates_d)(&x,&y)
#define MIN(x,y) (((x) <= (y))? (x): (y))
#define MAX(x,y) (((x) >= (y))? (x): (y))
#define ABS(x) (((x) >= 0)? (x): -(x))
#define round(x) ((int) ((x) + ((x >= 0)? 0.5: -0.5)))
#define round4(x) ((round(10000.0*(x))/10000.0))
char thindot [] = THINDOT;
char thickdot[] = THICKDOT;
char thin_ldot [] = THIN_LDOT;
char thick_ldot[] = THICK_LDOT;
int coord_system;
int verbose = 0;
double dash_mag = 1.0;
int thick_width = 1;
double tolerance = 2.0;
double arc_tolerance = 1.0;
int (*translate_coordinates)() = NULL;
int (*translate_coordinates_d)() = NULL;
double unitlength;
int cur_thickness = -1;
double ldot_diameter = 1.0/72.0;
char *dot_cmd = thindot;
char *ldot_cmd = thin_ldot;
double dot_xoffset;
double dot_yoffset;
double ldot_xoffset;
double ldot_yoffset;
static translate1(xp, yp)
int *xp, *yp;
{
*xp = *xp + 1;
*yp = *yp + 1;
}
static translate2(xp, yp)
int *xp, *yp;
{
*xp = *xp + 1;
*yp = TOP - *yp -1;
}
static translate1_d(xp, yp)
double *xp, *yp;
{
*xp = *xp + 1.0;
*yp = *yp + 1.0;
}
static translate2_d(xp, yp)
double *xp, *yp;
{
*xp = *xp + 1.0;
*yp = (double)TOP - *yp -1.0;
}
void genlatex_option(opt, optarg)
char opt, *optarg;
{
switch (opt) {
case 'f': /* set default text font */
{ int i;
for ( i = 1; i <= MAXFONT + 1; i++ )
if ( !strcmp(optarg, fontnames[i]) ) break;
if ( i > MAXFONT + 1 )
fprintf(stderr,
"warning: non-standard font name %s\n", optarg);
}
fontnames[0] = fontnames[1] = optarg;
break;
case 'l': /* set thin/thick line threshold */
thick_width = atoi(optarg);
break;
case 'd':
dash_mag = atof(optarg); /* set dash magnification */
break;
case 'v':
verbose = 1; /* verbose mode */
break;
case 's':
if (font_size <= 0 || font_size > MAXFONTSIZE) {
fprintf(stderr,
"warning: font size %d out of bounds\n", font_size);
}
break;
case 'm':
case 'L':
break;
default:
put_msg(Err_badarg, opt, "latex");
exit(1);
break;
}
}
void genlatex_start(objects)
F_compound *objects;
{
int tmp;
fontsizes[0] = fontsizes[1] = TEXFONTSIZE(font_size);
coord_system = objects->nwcorner.y;
unitlength = mag/objects->nwcorner.x;
switch (coord_system) {
case 1:
translate_coordinates = translate1;
translate_coordinates_d = translate1_d;
break;
case 2:
translate_coordinates = translate2;
translate_coordinates_d = translate2_d;
break;
default:
fprintf(stderr, "Wrong coordinate system; cannot continue\n");
return;
}
TRANS2(llx, lly, urx, ury);
if (llx > urx) SWAP(llx, urx)
if (lly > ury) SWAP(lly, ury)
/* LaTeX start */
fprintf(tfp, "\\setlength{\\unitlength}{%.4fin}%%\n",
round4(unitlength));
fprintf(tfp, "\\begin{picture}(%d,%d)(%d,%d)\n",
urx-llx, ury-lly, llx, lly);
}
void genlatex_end()
{
/* LaTeX ending */
fprintf(tfp, "\\end{picture}\n");
}
static set_linewidth(w)
int w;
{
int latex_w;
if (w == 0) return;
/* latex only knows thin lines or thick lines */
latex_w = (w >= thick_width)? THICKLINES: THINLINES;
if (latex_w != cur_thickness) {
cur_thickness = latex_w;
if (cur_thickness == THICKLINES) {
fprintf(tfp, "\\thicklines\n");
dot_cmd = thickdot;
dot_xoffset = round4(THICK_XOFF/unitlength);
dot_yoffset = round4(THICK_YOFF/unitlength);
ldot_cmd = thick_ldot;
ldot_xoffset = round4(THICK_LXOFF/unitlength);
ldot_yoffset = round4(THICK_LYOFF/unitlength);
}
else {
fprintf(tfp, "\\thinlines\n");
dot_cmd = thin_ldot;
dot_xoffset = round4(THIN_XOFF/unitlength);
dot_yoffset = round4(THIN_YOFF/unitlength);
ldot_cmd = thin_ldot;
ldot_xoffset = round4(THIN_LXOFF/unitlength);
ldot_yoffset = round4(THIN_LYOFF/unitlength);
}
}
}
void genlatex_line(l)
F_line *l;
{
F_point *p, *q;
int x, y, llx, lly, urx, ury, arrow;
if (verbose) fprintf(tfp, "%%\n%% Fig POLYLINE object\n%%\n");
set_linewidth(l->thickness);
p = l->points;
q = p->next;
if (q == NULL) { /* A single point line */
x = p->x; y = p->y;
TRANS(x, y);
fprintf(tfp, "\\put(%3d,%3d){\\makebox(%.4f,%.4f){%s}}\n",
x, y, dot_xoffset, dot_yoffset, dot_cmd);
return;
}
if (l->type == T_BOX) { /* A box */
x = p->x; y = p->y;
TRANS(x, y);
llx = urx = x;
lly = ury = y;
while (q != NULL) {
x = q->x; y = q->y;
TRANS(x, y);
if (x < llx) llx = x;
if (y < lly) lly = y;
if (x > urx) urx = x;
if (y > ury) ury = y;
q = q->next;
}
put_box (llx, lly, urx, ury, l->style, l->style_val);
return;
}
while (q != NULL) {
arrow = 0;
if (l->for_arrow && q->next == NULL)
arrow = 1;
if (l->back_arrow && p == l->points)
arrow = (arrow)? 2: -1;
single_line(p->x, p->y, q->x, q->y, arrow, l->style, l->style_val);
p = q;
q = q->next;
}
if (l->area_fill && (int)l->area_fill != DEFAULT)
fprintf(stderr, "Line area fill not implemented\n");
}
static single_line (x1, y1, x2, y2, arrow, style, val)
int x1, y1, x2, y2, arrow, style;
double val;
{
int dx, dy, sx, sy;
double l, m, deviation;
TRANS2(x1, y1, x2, y2);
dx = x2-x1;
dy = y2-y1;
/*** compute direction vector ***/
get_slope(dx, dy, &sx, &sy, arrow);
/*** compute line length in x-direction ***/
if (sx == 0) {
l = (double)abs(dy);
} else {
m = (double)abs(sy) / (double)abs(sx);
l = ((double)abs(dx) + m*(double)abs(dy)) / (1.0 + m*m);
deviation = fabs(l-abs(dx)) + fabs(m*l-abs(dy));
if (deviation > tolerance)
fprintf(stderr,
"Not a LaTeX slope (%d, %d), deviation %.1f pixels\n",
dx, dy, deviation);
}
l = round4(l);
/*** output letex command ***/
switch (style) {
case SOLID_LINE:
put_solidline(x1, y1, sx, sy, l, arrow);
break;
case DASH_LINE:
put_dashline(x1, y1, sx, sy, l, arrow, val);
break;
case DOTTED_LINE:
put_dotline(x1, y1, sx, sy, l, arrow, val);
break;
}
}
/*
* draw box
*/
static put_box (llx, lly, urx, ury, style, val)
int llx, lly, urx, ury, style;
double val;
{
int dlen;
switch (style) {
case SOLID_LINE:
fprintf(tfp, "\\put(%3d,%3d){\\framebox(%d,%d){}}\n",
llx, lly, urx-llx, ury-lly);
break;
case DASH_LINE:
dlen = round(val*dash_mag);
fprintf(tfp, "\\put(%3d,%3d){\\dashbox{%d}(%d,%d){}}\n",
llx, lly, dlen, urx-llx, ury-lly);
break;
case DOTTED_LINE:
put_dotline (llx, lly, 1, 0, (double)(urx-llx), 0, val);
put_dotline (llx, ury, 1, 0, (double)(urx-llx), 0, val);
put_dotline (llx, lly, 0, 1, (double)(ury-lly), 0, val);
put_dotline (urx, lly, 0, 1, (double)(ury-lly), 0, val);
break;
}
return;
}
/*
* draw a solid line given latex slope
*/
static put_solidline (x, y, sx, sy, l, arrow)
int x, y, sx, sy, arrow;
double l;
{
double cosine; /* cosine of line angle */
double dx, dy;
int x2, y2, n;
if (sx) {
cosine = (double)abs(sx) / hypot((double)sx, (double)sy);
x2 = (sx >= 0)? x + round(l): x - round(l);
y2 = y + round( ((sx>=0)? l: -l) * (double)sy / (double)sx);
}
else {
cosine = 1.0;
x2 = x;
y2 = (sy >= 0)? y + round(l): y - round(l);
}
if (sx == 0 || sy == 0 || (l/cosine)*unitlength >= MIN_LEN) {
switch (arrow) {
case 0: /* simple line */
fprintf(tfp, "\\put(%3d,%3d){\\line(%2d,%2d)", x, y, sx,sy);
break;
case 1: /* forward arrow */
fprintf(tfp, "\\put(%3d,%3d){\\vector(%2d,%2d)", x, y, sx,sy);
break;
case -1: /* backward arrow */
fprintf(tfp, "\\put(%3d,%3d){\\vector(%2d,%2d)", x2, y2, -sx,-sy);
break;
case 2: /* double arrow */
fprintf(tfp, "\\put(%3d,%3d){\\vector(%2d,%2d){ 0}}\n", x,y,-sx,-sy);
fprintf(tfp, "\\put(%3d,%3d){\\vector(%2d,%2d)", x, y, sx, sy);
break;
}
if (l == floor(l))
fprintf(tfp, "{%3.0f}}\n", l);
else
fprintf(tfp, "{%7.3f}}\n", l);
}
else {
n = 2 * (l/cosine) / (ldot_diameter/unitlength);
fprintf(stderr, "Line too short; will do %d dots\n", n);
dx = l / (double)n;
if (sx < 0) dx = -dx;
dy = dx * (double)sy / (double)sx;
fprintf(tfp,
"\\multiput(%3d,%3d)(%.5f,%.5f){%d}{\\makebox(%.4f,%.4f){%s}}\n",
x, y, dx, dy, n+1, ldot_xoffset, ldot_yoffset, ldot_cmd);
if (arrow == 1 || arrow == 2) /* forward arrow */
fprintf(tfp, "\\put(%3d,%3d){\\vector(%2d,%2d){0}}\n", x2,y2, sx,sy);
if (arrow == -1 || arrow == 2) /* backward arrow */
fprintf(tfp, "\\put(%3d,%3d){\\vector(%2d,%2d){0}}\n", x,y, -sx,-sy);
}
}
/*
* draw a dashed line given latex slope
*/
static put_dashline (x, y, sx, sy, l, arrow, val)
int x, y, sx, sy, arrow;
double l;
double val;
{
double cosine; /* cosine of line angle */
double nd; /* number of dashes and gaps fitting on line */
int n; /* nd rounded to the nearest odd integer */
double dl; /* actual x-length of each dash */
double dg; /* actual x-length of each gap */
double dx, dy; /* step between dashes */
int x2, y2;
if (sx) {
cosine = (double)abs(sx) / hypot((double)sx, (double)sy);
x2 = (sx >= 0)? x + round(l): x - round(l);
y2 = y + round( ((sx>=0)? l: -l) * (double)sy / (double)sx );
}
else {
cosine = 1.0;
x2 = x;
y2 = (sy >= 0)? y + round(l): y - round(l);
}
/*** compute number of dashes, length of dashes and gaps ***/
nd = l / (val*dash_mag*cosine);
n = (int) (rint((nd + 1.0)/2.0)*2 - 1);
dl = l / (double)n;
if (sx && sy && (dl/cosine)*unitlength < MIN_LEN) {
fprintf(stderr, "Dash too small; using larger dash\n");
dl = MIN_LEN/unitlength * cosine;
nd = l / dl;
n = (int) (rint((nd + 1.0)/2.0)*2 - 1);
}
if (2*dl >= l || (sx && sy && (l/cosine)*unitlength < MIN_LEN)) {
fprintf(stderr, "Dashed line too short; drawing solid line\n");
put_solidline (x, y, sx, sy, l, arrow);
return;
}
dg = (l - (n/2+1)*dl) / (double)(n/2);
if (sx) {
dx = dl+dg;
if (sx < 0) dx = -dx;
dy = dx * (double)sy / (double)sx;
}
else {
dx = 0.0;
dy = dl+dg;
if (sy < 0) dy = -dy;
}
/*** draw dashed line ***/
fprintf(tfp, "\\multiput(%3d,%3d)(%.5f,%.5f){%d}{\\line(%2d,%2d){%7.3f}}\n",
x, y, dx, dy, n/2+1, sx, sy, dl);
/*** draw arrow heads ***/
if (arrow == 1 || arrow == 2)
fprintf(tfp, "\\put(%3d,%3d){\\vector(%2d,%2d){0}}\n", x2, y2, sx, sy);
if (arrow == -1 || arrow == 2)
fprintf(tfp, "\\put(%3d,%3d){\\vector(%2d,%2d){0}}\n", x, y, -sx, -sy);
}
/*
* draw a dotted line given latex slope
*/
static put_dotline (x, y, sx, sy, l, arrow, val)
int x, y, sx, sy, arrow;
double l;
double val;
{
double cosine; /* cosine of line angle */
double nd; /* number of dots fitting on line */
int n; /* nd rounded to the nearest integer */
double dx, dy; /* step between dashes */
int x2, y2;
cosine = (sx)? (double)abs(sx) / hypot((double)sx, (double)sy): 1.0;
/*** compute step width ***/
nd = l / (3*val*cosine);
n = rint(nd);
dx = l / (double)n;
if (sx) {
dx = l / (double)n;
if (sx < 0) dx = -dx;
dy = dx * (double)sy / (double)sx;
}
else {
dx = 0.0;
dy = l / (double)n;
if (sy < 0) dy = -dy;
}
/*** draw arrow heads ***/
if (arrow == 1 || arrow == 2) {
/* forward arrow */
if (sx) {
x2 = (sx >= 0)? x + round(l): x - round(l);
y2 = y + round( ((sx>=0)? l: -l) * (double)sy / (double)sx );
}
else {
x2 = x;
y2 = (sy >= 0)? y + round(l): y - round(l);
}
fprintf(tfp, "\\put(%3d,%3d){\\vector(%2d,%2d){0}}\n", x2, y2, sx, sy);
n--;
}
if (arrow == -1 || arrow == 2) {
fprintf(tfp, "\\put(%3d,%3d){\\vector(%2d,%2d){0}}\n", x, y, -sx, -sy);
x = round(x + dx);
y = round(y + dy);
n--;
}
/*** draw dotted line ***/
fprintf(tfp, "\\multiput(%3d,%3d)(%.5f,%.5f){%d}{\\makebox(%.4f,%.4f){%s}}\n",
x, y, dx, dy, n+1, dot_xoffset, dot_yoffset, dot_cmd);
}
void genlatex_spline(s)
F_spline *s;
{
fprintf(stderr, "Can't generate spline; omitting object\n");
}
void genlatex_ellipse(e)
F_ellipse *e;
{
int x, y, d, dx, dy;
if (verbose) fprintf(tfp, "%%\n%% Fig ELLIPSE\n%%\n");
set_linewidth(e->thickness);
switch (e->style) {
case SOLID_LINE:
break;
case DASH_LINE:
fprintf(stderr, "Dashed circles and elipses not supported\n");
break;
case DOTTED_LINE:
fprintf(stderr, "Dotted circles and elipses not supported\n");
break;
}
x = e->center.x;
y = e->center.y;
TRANS(x, y);
if ((e->type == T_CIRCLE_BY_RAD || e->type == T_CIRCLE_BY_DIA)
&& e->radiuses.x*unitlength <= MAXCIRCLERAD) {
d = 2 * e->radiuses.x;
if (e->area_fill == BLACK_FILL)
fprintf(tfp, "\\put(%3d,%3d){\\circle*{%d}}\n", x, y, d);
else {
fprintf(tfp, "\\put(%3d,%3d){\\circle{%d}}\n", x, y, d);
if (e->area_fill && (int)e->area_fill != DEFAULT)
fprintf(stderr, "Circle area fill not implemented\n");
}
} else {
dx = 2 * e->radiuses.x;
dy = 2 * e->radiuses.y;
fprintf(tfp, "\\put(%3d,%3d){\\oval(%d,%d)}\n", x, y, dx, dy);
if (e->area_fill && (int)e->area_fill != DEFAULT)
fprintf(stderr, "Ellipse area fill not implemented\n");
}
}
void genlatex_text(t)
F_text *t;
{
int x, y;
char *tpos, *cp;
if (verbose) fprintf(tfp, "%%\n%% Fig TEXT object\n%%\n");
x = t->base_x;
y = t->base_y;
TRANS(x, y);
switch (t->type) {
case T_LEFT_JUSTIFIED:
case DEFAULT:
tpos = "[lb]";
break;
case T_CENTER_JUSTIFIED:
tpos = "[b]";
break;
case T_RIGHT_JUSTIFIED:
tpos = "[rb]";
break;
default:
fprintf(stderr, "Text incorrectly positioned\n");
}
/* raisebox is used to position text at baseline */
fprintf(tfp,
"\\put(%3d,%3d){\\makebox(0,0)%s{\\raisebox{0pt}[0pt][0pt]",
x, y, tpos);
fprintf(tfp, "{\\%s%s ", TEXFONTSIZE(t->size), TEXFONT(t->font));
if (t->font && t->font !=DEFAULT)
/* this loop escapes characters "$&%#_{}" */
/* and deleted characters "~^\" */
for(cp = t->cstring; *cp; cp++) {
if (strchr("$&%#_{}", *cp)) (void)fputc('\\', tfp);
if (strchr("~^\\", *cp))
fprintf(stderr,
"Bad character in text object '%c'\n" ,*cp);
else
(void)fputc(*cp, tfp);
}
else
fprintf(tfp, "%s", t->cstring);
fprintf(tfp, "}}}\n");
}
void genlatex_arc(a)
F_arc *a;
/*
* Approximates an arc by a sequence of quarter ovals.
*
* Example:
*
* Arc with center at (0,0) and radius 10 from +45 degree to +225 degree
* (arc from p1 = (7.07, 7.07) to p2 = (-7.07, -7.07) counterclockwise).
* This arc is approximated by three quarter ovals, one for each quadrant
* through which the arc goes:
*
* 1. quarter oval from p1 to the intersection of arc and y-axis,
* i.e., from (7.07, 7.07) to (0, 10) in quadrant 0
*
* \put(0, 7.07){\oval(14.14, 5.86)[tr]}
*
* 2. quarter oval from intersection arc/y-axis to intersection arc/x-axis
* i.e., from (0, 10) to (-10, 0) in quadrant 1
*
* \put(0, 0){\oval(20,20)[tl]}
*
* 3. quarter oval from p1 to the intersection of arc and y-axis,
* i.e., from (-10, 0) to (-7.07, -7.07) in quadrant 2
*
* \put(-7.07, 0){\oval(5.86, 14.14)[bl]}
*/
{
F_pos p1, p2, pq[4];
double cx, cy;
double v1x, v1y, v2x, v2y;
double r, angle1, angle2;
int q1, q2;
int p1_arrow, p2_arrow;
static char *ad1[4] = { " 0,-1", " 1, 0", " 0, 1", "-1, 0" };
static char *ad2[4] = { "-1, 0", " 0,-1", " 1, 0", " 0, 1" };
set_linewidth(a->thickness);
switch (a->style) {
case SOLID_LINE:
break;
case DASH_LINE:
fprintf(stderr, "Dashed arcs not supported\n");
break;
case DOTTED_LINE:
fprintf(stderr, "Dotted arcs not supported\n");
break;
}
if (a->direction == 1) {
p1 = a->point[0];
p2 = a->point[2];
p1_arrow = (a->back_arrow != NULL);
p2_arrow = (a->for_arrow != NULL);
}
else {
p1 = a->point[2];
p2 = a->point[0];
p1_arrow = (a->for_arrow != NULL);
p2_arrow = (a->back_arrow != NULL);
}
cx = a->center.x;
cy = a->center.y;
TRANS2(p1.x, p1.y, p2.x, p2.y);
TRANSD(cx, cy);
/*** compute vectors and angles from arc center to p1, p2 ***/
v1x = (double)p1.x - cx;
v1y = (double)p1.y - cy;
v2x = (double)p2.x - cx;
v2y = (double)p2.y - cy;
angle1 = atan2(v1y, v1x) * rad2deg;
angle2 = atan2(v2y, v2x) * rad2deg;
if (angle1 < 0.0)
angle1 += 360.0;
if (angle2 < 0.0)
angle2 += 360.0;
/* compute arc radius */
r = hypot(v1x, v1y);
/*** compute intersection of arc with x and y axis (origin at cx, cy) */
pq[0].x = round(cx);
pq[0].y = round(cy + r);
pq[1].x = round(cx - r);
pq[1].y = round(cy);
pq[2].x = round(cx);
pq[2].y = round(cy - r);
pq[3].x = round(cx + r);
pq[3].y = round(cy);
/*** compute in which quadrants p1 and p2 are located ***/
q1 = (int)(angle1/90.0);
q2 = (int)(angle2/90.0);
if (fabs(angle1 - 90.0*q1) > arc_tolerance
|| fabs(angle2 - 90.0*q2) > arc_tolerance)
fprintf(stderr, "Approximating arc by ovals\n");
/*** Draw arc ***/
if (p1_arrow)
fprintf(tfp, "\\put(%3d,%3d){\\vector(%s){0}}\n", p1.x, p1.y, ad1[q1]);
while (q1 != q2) {
put_quarter(p1, pq[q1], q1);
p1 = pq[q1];
q1 = (q1 + 1) % 4;
}
put_quarter(p1, p2, q1);
if (p2_arrow)
fprintf(tfp, "\\put(%3d,%3d){\\vector(%s){0}}\n", p2.x, p2.y, ad2[q2]);
if (a->area_fill && (int)a->area_fill != DEFAULT)
fprintf(stderr, "Arc area fill not implemented\n");
}
static put_quarter(p1, p2, q)
F_pos p1, p2;
int q;
/*
* Draw quarter oval from p1 to p2 in quadrant q
*/
{
char *opt;
int px, py, dx, dy;
dx = 2*ABS(p1.x - p2.x);
dy = 2*ABS(p1.y - p2.y);
if (dx == 0 && dy == 0)
return;
switch (q) {
case 0:
px = MIN(p1.x, p2.x);
py = MIN(p1.y, p2.y);
opt = "tr";
break;
case 1:
px = MAX(p1.x, p2.x);
py = MIN(p1.y, p2.y);
opt = "tl";
break;
case 2:
px = MAX(p1.x, p2.x);
py = MAX(p1.y, p2.y);
opt = "bl";
break;
case 3:
px = MIN(p1.x, p2.x);
py = MAX(p1.y, p2.y);
opt = "br";
break;
}
fprintf(tfp, "\\put(%3d,%3d){\\oval(%3d,%3d)[%s]}\n", px, py, dx, dy, opt);
}
struct driver dev_latex = {
genlatex_option,
genlatex_start,
genlatex_arc,
genlatex_ellipse,
genlatex_line,
genlatex_spline,
genlatex_text,
genlatex_end,
EXCLUDE_TEXT
};