src/meta/mgraph.c

#ifndef lint
static const char       RCSid[] = "$Id: mgraph.c,v 1.1 2003/02/22 02:07:26 greg Exp $";
#endif
/*
 *  mgraph.c - routines for plotting graphs from variables.
 *
 *     6/23/86
 *
 *     Greg Ward Larson
 */

#include  <stdio.h>
#include  <string.h>

#include  "meta.h"
#include  "mgvars.h"
#include  "mgraph.h"

extern char  *progname;                 /* argv[0] */

extern double  goodstep(), floor(), ceil(), sin(), cos();

static BOUNDS  xbounds, ybounds;        /* the boundaries for the graph */

static double  period = DEFPERIOD;      /* period for polar plot */

static double  axbegin, axsize;         /* the mapped x axis boundaries */
static double  aybegin, aysize;         /* the mapped y axis boundaries */

static int  npltbl[MAXCUR];             /* plottable points per curve */

static double  lastx, lasty;            /* last curve postion */
static int  nplottable;                 /* number of plottable points */
static int  nplotted;                   /* number of plotted points */

static void getbounds(void);
static void polaraxis(void);
static void makeaxis(void);
static void plotcurves(void);
static void cartaxis(void);
static void stretchbounds(int  c, double  x, double  y);
static void boxstring(int  xmin, int ymin, int xmax, int ymax,
        char  *s, int  d, int width, int color);
static void drawcircle(int  x, int y, int r, int  typ, int wid, int col);
static int rconv(double  r);
static int xconv(double  x);
static int yconv(double  y);
static void csymbol(int  c, double  u, double v);
static int cmline(int  c, int  x, int y);
static void cmsymbol(int  c, int  x, int y);
static int inbounds(double  x, double y);
static void climline(int  c, double  x, double y, double xout, double yout);
static void nextpoint(register int  c, double  x, double  y);
static void cline(int  c, double  u1, double v1, double u2, double v2);


void
mgraph(void)                    /* plot the current graph */
{
                                        /* load the symbol file */
        if (gparam[SYMFILE].flags & DEFINED)
                minclude(gparam[SYMFILE].v.s);
                                        /* check for polar plot */
        if (gparam[PERIOD].flags & DEFINED)
                period = varvalue(gparam[PERIOD].name);

        getbounds();                    /* get the boundaries */
        makeaxis();                     /* draw the coordinate axis */
        plotcurves();                   /* plot the curves */

        mendpage();                     /* advance page */
}


void
getbounds(void)                 /* compute the boundaries */
{
        int  i;

        xbounds.min = gparam[XMIN].flags & DEFINED ?
                         varvalue(gparam[XMIN].name) - FTINY :
                         FHUGE ;
        xbounds.max = gparam[XMAX].flags & DEFINED ?
                         varvalue(gparam[XMAX].name) + FTINY :
                         -FHUGE ;
        ybounds.min = gparam[YMIN].flags & DEFINED ?
                         varvalue(gparam[YMIN].name) - FTINY :
                         FHUGE ;
        ybounds.max = gparam[YMAX].flags & DEFINED ?
                         varvalue(gparam[YMAX].name) + FTINY :
                         -FHUGE ;

        nplottable = 0;
        for (i = 0; i < MAXCUR; i++) {
                npltbl[i] = 0;
                mgcurve(i, stretchbounds);
                nplottable += npltbl[i];
        }
        if (nplottable == 0) {
                fprintf(stderr, "%s: no plottable data\n", progname);
                quit(1);
        }

        xbounds.step = gparam[XSTEP].flags & DEFINED ?
                          varvalue(gparam[XSTEP].name) :
                          period > FTINY ?
                                DEFPLSTEP*period :
                                goodstep(xbounds.max - xbounds.min) ;
        if (!(gparam[XMIN].flags & DEFINED))
                xbounds.min = floor(xbounds.min/xbounds.step) *
                                        xbounds.step;
        if (!(gparam[XMAX].flags & DEFINED))
                xbounds.max = ceil(xbounds.max/xbounds.step) *
                                        xbounds.step;
        ybounds.step = gparam[YSTEP].flags & DEFINED ?
                          varvalue(gparam[YSTEP].name) :
                          period > FTINY ?
                                goodstep((ybounds.max - ybounds.min)*1.75) :
                                goodstep(ybounds.max - ybounds.min) ;
        if (!(gparam[YMIN].flags & DEFINED))
                ybounds.min = floor(ybounds.min/ybounds.step) *
                                        ybounds.step;
        if (!(gparam[YMAX].flags & DEFINED))
                ybounds.max = ceil(ybounds.max/ybounds.step) *
                                        ybounds.step;
        if (gparam[XMAP].flags & DEFINED) {
                axbegin = funvalue(gparam[XMAP].name, 1, &xbounds.min);
                axsize = funvalue(gparam[XMAP].name, 1, &xbounds.max);
                axsize -= axbegin;
        } else {
                axbegin = xbounds.min;
                axsize = xbounds.max;
                axsize -= axbegin;
        }
        if (gparam[YMAP].flags & DEFINED) {
                aybegin = funvalue(gparam[YMAP].name, 1, &ybounds.min);
                aysize = funvalue(gparam[YMAP].name, 1, &ybounds.max);
                aysize -= aybegin;
        } else {
                aybegin = ybounds.min;
                aysize = ybounds.max;
                aysize -= aybegin;
        }
}


void
makeaxis(void)                          /* draw the coordinate axis */
{
        char  stmp[64];

        if (period > FTINY)
                polaraxis();
        else
                cartaxis();
                                                /* x axis label */
        if (gparam[XLABEL].flags & DEFINED)
                boxstring(XL_L,XL_D,XL_R,XL_U,gparam[XLABEL].v.s,'r',0,0);
                                                /* x mapping */
        if (gparam[XMAP].flags & DEFINED) {
                mgtoa(stmp, &gparam[XMAP]);
                boxstring(XM_L,XM_D,XM_R,XM_U,stmp,'r',0,0);
        }
                                                /* y axis label */
        if (gparam[YLABEL].flags & DEFINED)
                boxstring(YL_L,YL_D,YL_R,YL_U,gparam[YLABEL].v.s,'u',0,0);
                                                /* y mapping */
        if (gparam[YMAP].flags & DEFINED) {
                mgtoa(stmp, &gparam[YMAP]);
                boxstring(YM_L,YM_D,YM_R,YM_U,stmp,'u',0,0);
        }
                                                /* title */
        if (gparam[TITLE].flags & DEFINED)
                boxstring(TI_L,TI_D,TI_R,TI_U,gparam[TITLE].v.s,'r',2,0);
                                                /* subtitle */
        if (gparam[SUBTITLE].flags & DEFINED)
                boxstring(ST_L,ST_D,ST_R,ST_U,gparam[SUBTITLE].v.s,'r',1,0);
                                                /* legend */
        if (gparam[LEGEND].flags & DEFINED)
                mtext(LT_X, LT_Y, gparam[LEGEND].v.s, CPI, 0);
}


void
polaraxis(void)                         /* print polar coordinate axis */
{
        int  lw, tstyle, t0, t1;
        double  d, d1, ybeg;
        char  stmp[64], *fmt, *goodformat();
                                                /* get tick style */
        if (gparam[TSTYLE].flags & DEFINED)
                tstyle = varvalue(gparam[TSTYLE].name) + 0.5;
        else
                tstyle = DEFTSTYLE;
                                                /* start of numbering */
        ybeg = ceil(ybounds.min/ybounds.step)*ybounds.step;
                                                /* theta (x) numbering */
        fmt = goodformat(xbounds.step);
        for (d = 0.0; d < period-FTINY; d += xbounds.step) {
                sprintf(stmp, fmt, d);
                d1 = d*(2*PI)/period;
                t0 = TN_X + TN_R*cos(d1) + .5;
                if (t0 < TN_X)
                        t0 -= strlen(stmp)*CWID;
                mtext(t0,(int)(TN_Y+TN_R*sin(d1)+.5),stmp,CPI,0);
        }
                                                /* radius (y) numbering */
        fmt = goodformat(ybounds.step);
        lw = PL_R+RN_S;
        for (d = ybeg; d <= ybounds.max+FTINY; d += ybounds.step) {
                t0 = rconv(d);
                if (t0 >= lw+RN_S || t0 <= lw-RN_S) {
                        sprintf(stmp, fmt, d);
                        mtext(RN_X+t0-strlen(stmp)*(CWID/2),RN_Y,stmp,CPI,0);
                        lw = t0;
                }
        }
                                                /* frame */
        if (gparam[FTHICK].flags & DEFINED)
                lw = varvalue(gparam[FTHICK].name) + 0.5;
        else
                lw = DEFFTHICK;
        if (lw-- > 0) {
                drawcircle(PL_X,PL_Y,PL_R,0,lw,0);
                switch (tstyle) {
                case 1:         /* outside */
                        t0 = 0; t1 = TLEN; break;
                case 2:         /* inside */
                        t0 = TLEN; t1 = 0; break;
                case 3:         /* accross */
                        t0 = TLEN/2; t1 = TLEN/2; break;
                default:        /* none */
                        t0 = t1 = 0; break;
                }
                if (t0 + t1) {
                        for (d = 0.0; d < 2*PI-FTINY;
                                        d += xbounds.step*(2*PI)/period) {
                                mline((int)(PL_X+(PL_R-t0)*cos(d)+.5),
                                        (int)(PL_Y+(PL_R-t0)*sin(d)+.5),
                                        0, lw, 0);
                                mdraw((int)(PL_X+(PL_R+t1)*cos(d)+.5),
                                        (int)(PL_Y+(PL_R+t1)*sin(d)+.5));
                        }
                }
        }
                                                /* origin */
        if (gparam[OTHICK].flags & DEFINED)
                lw = varvalue(gparam[OTHICK].name) + 0.5;
        else
                lw = DEFOTHICK;
        if (lw-- > 0) {
                mline(PL_X-PL_R,PL_Y,0,lw,0);
                mdraw(PL_X+PL_R,PL_Y);
                mline(PL_X,PL_Y-PL_R,0,lw,0);
                mdraw(PL_X,PL_Y+PL_R);
                if (tstyle > 0)
                        for (d = ybeg; d <= ybounds.max+FTINY;
                                        d += ybounds.step) {
                                t0 = rconv(d);
                                mline(PL_X+t0,PL_Y-TLEN/2,0,lw,0);
                                mdraw(PL_X+t0,PL_Y+TLEN/2);
                                mline(PL_X-TLEN/2,PL_Y+t0,0,lw,0);
                                mdraw(PL_X+TLEN/2,PL_Y+t0);
                                mline(PL_X-t0,PL_Y-TLEN/2,0,lw,0);
                                mdraw(PL_X-t0,PL_Y+TLEN/2);
                                mline(PL_X-TLEN/2,PL_Y-t0,0,lw,0);
                                mdraw(PL_X+TLEN/2,PL_Y-t0);
                        }
        }
                                                /* grid */
        if (gparam[GRID].flags & DEFINED)
                lw = varvalue(gparam[GRID].name);
        else
                lw = DEFGRID;
        if (lw-- > 0) {
                for (d = 0.0; d < PI-FTINY; d += xbounds.step*(2*PI)/period) {
                        mline((int)(PL_X+PL_R*cos(d)+.5),
                                (int)(PL_Y+PL_R*sin(d)+.5),2,0,0);
                        mdraw((int)(PL_X-PL_R*cos(d)+.5),
                                (int)(PL_Y-PL_R*sin(d)+.5));
                }
                for (d = ybeg; d <= ybounds.max + FTINY; d += ybounds.step)
                        drawcircle(PL_X,PL_Y,rconv(d),2,0,0);
        }
}

void
cartaxis(void)                          /* print Cartesian coordinate axis */
{
        int  lw, t0, t1, tstyle;
        double  d, xbeg, ybeg;
        char  stmp[64], *fmt, *goodformat();
        register int  i;
                                                /* get tick style */
        if (gparam[TSTYLE].flags & DEFINED)
                tstyle = varvalue(gparam[TSTYLE].name) + 0.5;
        else
                tstyle = DEFTSTYLE;
                                                /* start of numbering */
        xbeg = ceil(xbounds.min/xbounds.step)*xbounds.step;
        ybeg = ceil(ybounds.min/ybounds.step)*ybounds.step;
        
                                                /* x numbering */
        fmt = goodformat(xbounds.step);
        lw = 2*AX_L-AX_R;
        for (d = xbeg;
                        d <= xbounds.max + FTINY;
                        d += xbounds.step)
                if ((i = xconv(d)) >= lw+XN_S || i <= lw-XN_S) {
                        sprintf(stmp, fmt, d);
                        mtext(i-strlen(stmp)*(CWID/2)+XN_X,XN_Y,stmp,CPI,0);
                        lw = i;
                }
                                                /* y numbering */
        fmt = goodformat(ybounds.step);
        lw = 2*AX_D-AX_U;
        for (d = ybeg;
                        d <= ybounds.max + FTINY;
                        d += ybounds.step)
                if ((i = yconv(d)) >= lw+YN_S || i <= lw-YN_S) {
                        sprintf(stmp, fmt, d);
                        mtext(YN_X-strlen(stmp)*CWID,i+YN_Y,stmp,CPI,0);
                        lw = i;
                }
                                                /* frame */
        if (gparam[FTHICK].flags & DEFINED)
                lw = varvalue(gparam[FTHICK].name) + 0.5;
        else
                lw = DEFFTHICK;
        if (lw-- > 0) {
                mline(AX_L,AX_D,0,lw,0);
                mdraw(AX_R,AX_D);
                mdraw(AX_R,AX_U);
                mdraw(AX_L,AX_U);
                mdraw(AX_L,AX_D);
                switch (tstyle) {
                case 1:         /* outside */
                        t0 = 0; t1 = TLEN; break;
                case 2:         /* inside */
                        t0 = TLEN; t1 = 0; break;
                case 3:         /* accross */
                        t0 = TLEN/2; t1 = TLEN/2; break;
                default:        /* none */
                        t0 = t1 = 0; break;
                }
                if (t0 + t1) {
                        for (d = xbeg;
                                        d <= xbounds.max + FTINY;
                                        d += xbounds.step) {
                                i = xconv(d);
                                mline(i,AX_D+t0,0,lw,0);
                                mdraw(i,AX_D-t1);
                                mline(i,AX_U-t0,0,lw,0);
                                mdraw(i,AX_U+t1);
                        }
                        for (d = ybeg;
                                        d <= ybounds.max + FTINY;
                                        d += ybounds.step) {
                                i = yconv(d);
                                mline(AX_L+t0,i,0,lw,0);
                                mdraw(AX_L-t1,i);
                                mline(AX_R-t0,i,0,lw,0);
                                mdraw(AX_R+t1,i);
                        }
                }
        }
                                                /* origin */
        if (gparam[OTHICK].flags & DEFINED)
                lw = varvalue(gparam[OTHICK].name) + 0.5;
        else
                lw = DEFOTHICK;
        if (lw-- > 0) {
                i = yconv(0.0);
                if (i >= AX_D && i <= AX_U) {
                        mline(AX_L,i,0,lw,0);
                        mdraw(AX_R,i);
                        if (tstyle > 0)
                                for (d = xbeg; d <= xbounds.max+FTINY;
                                                d += xbounds.step) {
                                        mline(xconv(d),i+TLEN/2,0,lw,0);
                                        mdraw(xconv(d),i-TLEN/2);
                                }
                }
                i = xconv(0.0);
                if (i >= AX_L && i <= AX_R) {
                        mline(i,AX_D,0,lw,0);
                        mdraw(i,AX_U);
                        if (tstyle > 0)
                                for (d = ybeg; d <= ybounds.max+FTINY;
                                                d += ybounds.step) {
                                        mline(i+TLEN/2,yconv(d),0,lw,0);
                                        mdraw(i-TLEN/2,yconv(d));
                                }
                }
        }
                                                /* grid */
        if (gparam[GRID].flags & DEFINED)
                lw = varvalue(gparam[GRID].name);
        else
                lw = DEFGRID;
        if (lw-- > 0) {
                for (d = xbeg;
                                d <= xbounds.max + FTINY;
                                d += xbounds.step) {
                        i = xconv(d);
                        mline(i,AX_D,2,0,0);
                        mdraw(i,AX_U);
                }
                for (d = ybeg;
                                d <= ybounds.max + FTINY;
                                d += ybounds.step) {
                        i = yconv(d);
                        mline(AX_L,i,2,0,0);
                        mdraw(AX_R,i);
                }
        }
}

void
plotcurves(void)                                /* plot the curves */
{
        int  i, j, k;

        for (i = 0; i < MAXCUR; i++) {
                nplottable = nplotted = 0;
                lastx = FHUGE;
                if (mgcurve(i, nextpoint) > 0 &&
                                cparam[i][CLABEL].flags & DEFINED) {
                        j = (LE_U-LE_D)/MAXCUR;
                        k = LE_U - i*j;
                        mtext(LE_L+(LE_R-LE_L)/8,k+j/3,
                                        cparam[i][CLABEL].v.s,CPI,0);
                        cmsymbol(i,LE_L,k);
                        if (cmline(i,LE_L,k) == 0)
                            mdraw(LE_R-(LE_R-LE_L)/4,k);
                }
        }
}

void
nextpoint(                      /* plot the next point for c */
        register int  c,
        double  x,
        double  y
)
{
        if (inbounds(x, y)) {

                if (!(cparam[c][CNPOINTS].flags & DEFINED) ||
                                nplotted * npltbl[c] <= nplottable *
                                (int)varvalue(cparam[c][CNPOINTS].name) ) {
                        csymbol(c, x, y);
                        nplotted++;
                }
                nplottable++;
                if (lastx != FHUGE)
                        climline(c, x, y, lastx, lasty);

        } else if (inbounds(lastx, lasty)) {

                climline(c, lastx, lasty, x, y);

        }
        lastx = x;
        lasty = y;
}


void
stretchbounds(                  /* stretch our boundaries */
        int  c,
        double  x,
        double  y
)
{
        if (gparam[XMIN].flags & DEFINED &&
                        x < xbounds.min)
                return;
        if (gparam[XMAX].flags & DEFINED &&
                        x > xbounds.max)
                return;
        if (gparam[YMIN].flags & DEFINED &&
                        y < ybounds.min)
                return;
        if (gparam[YMAX].flags & DEFINED &&
                        y > ybounds.max)
                return;

        if (x < xbounds.min)
                xbounds.min = x;
        if (x > xbounds.max)
                xbounds.max = x;
        if (y < ybounds.min)
                ybounds.min = y;
        if (y > ybounds.max)
                ybounds.max = y;
                
        npltbl[c]++;
}


#define  exp10(x)       exp((x)*2.3025850929940456)

double
goodstep(               /* determine a good step for the interval */
        double  interval
)
{
        static int  steps[] = {50, 20, 10, 5, 2, 1};
        double  fact, exp(), log10(), floor();
        int  i;

        if (interval <= FTINY)
                return(1.0);
        fact = exp10(floor(log10(interval)))/10;
        interval /= fact * MINDIVS;
        for (i = 0; interval < steps[i]; i++)
                ;
        return(steps[i] * fact);
}

#undef  exp10


int
xconv(                  /* convert x to meta coords */
        double  x
)
{
        if (gparam[XMAP].flags & DEFINED)
                x = funvalue(gparam[XMAP].name, 1, &x);
        x = (x - axbegin)/axsize;
        return( AX_L + (int)(x*(AX_R-AX_L)) );
}


int
yconv(                  /* convert y to meta coords */
        double  y
)
{
        if (gparam[YMAP].flags & DEFINED)
                y = funvalue(gparam[YMAP].name, 1, &y);
        y = (y - aybegin)/aysize;
        return( AX_D + (int)(y*(AX_U-AX_D)) );
}


void
pconv(          /* convert theta and radius to meta coords */
        int  *xp,
        int  *yp,
        double  t,
        double  r
)
{
        t *= (2.*PI)/period;
        r = rconv(r);
        *xp = r*cos(t) + (PL_X+.5);
        *yp = r*sin(t) + (PL_Y+.5);
}


int
rconv(                  /* convert radius to meta coords */
        double  r
)
{
        if (gparam[YMAP].flags & DEFINED)
                r = funvalue(gparam[YMAP].name, 1, &r);

        return((r - aybegin)*PL_R/aysize + .5);
}
        

void
boxstring(      /* put string in box */
        int  xmin,
        int ymin,
        int xmax,
        int ymax,
        char  *s,
        int  d,
        int width,
        int color
)
{
        register long  size;

        if (d == 'u' || d == 'd') {             /* up or down */
                size = strlen(s)*(xmax-xmin)/ASPECT;
                size -= ymax-ymin;
                size /= 2;
                if (size < 0) {                         /* center */
                        ymin -= size;
                        ymax += size;
                }
        } else {                                /* left or right */
                size = strlen(s)*(ymax-ymin)/ASPECT;
                size -= xmax-xmin;
                size /= 2;
                if (size < 0) {                         /* center */
                        xmin -= size;
                        xmax += size;
                }
        }
        mvstr(xmin, ymin, xmax, ymax, s, d, width, color);      /* print */
}


char *
goodformat(                     /* return a suitable format string for d */
        double  d
)
{
        static char  *f[5] = {"%.0f", "%.1f", "%.2f", "%.3f", "%.4f"};
        double  floor();
        register int  i;

        if (d < 0.0)
                d = -d;
        if (d > 1e-4 && d < 1e6)
                for (i = 0; i < 5; i++) {
                        if (d - floor(d+FTINY) <= FTINY)
                                return(f[i]);
                        d *= 10.0;
                }
        return("%.1e");
}


void
drawcircle(     /* draw a circle */
        int  x,
        int y,
        int r,
        int  typ,
        int wid,
        int col
)
{
        double  d;

        if (r <= 0)
                return;
        mline(x+r, y, typ, wid, col);
        for (d = 2*PI*PL_F; d <= 2*PI+FTINY; d += 2*PI*PL_F)
                mdraw((int)(x+r*cos(d)+.5), (int)(y+r*sin(d)+.5));
}


void
climline(       /* print line from/to out of bounds */
        int  c,
        double  x,
        double y,
        double xout,
        double yout
)
{
        for ( ; ; )
                if (xout < xbounds.min) {
                        yout = y + (yout - y)*(xbounds.min - x)/(xout - x);
                        xout = xbounds.min;
                } else if (yout < ybounds.min) {
                        xout = x + (xout - x)*(ybounds.min - y)/(yout - y);
                        yout = ybounds.min;
                } else if (xout > xbounds.max) {
                        yout = y + (yout - y)*(xbounds.max - x)/(xout - x);
                        xout = xbounds.max;
                } else if (yout > ybounds.max) {
                        xout = x + (xout - x)*(ybounds.max - y)/(yout - y);
                        yout = ybounds.max;
                } else {
                        cline(c, x, y, xout, yout);
                        break;
                }        
}


void
cline(          /* print a curve line */
        int  c,
        double  u1,
        double v1,
        double u2,
        double v2
)
{
        int  x, y;
        double  ustep, vstep;
        
        if (period > FTINY) {           /* polar */
                if (u1 > u2) {
                        ustep = u1; u1 = u2; u2 = ustep;
                        vstep = v1; v1 = v2; v2 = vstep;
                }
                pconv(&x, &y, u1, v1);
                if (cmline(c, x, y) < 0)
                        return;
                ustep = period*PL_F;
                if (u2-u1 > ustep) {
                        vstep = ustep*(v2-v1)/(u2-u1);
                        while ((u1 += ustep) < u2) {
                                v1 += vstep;
                                pconv(&x, &y, u1, v1);
                                mdraw(x, y);
                        }
                }
                pconv(&x, &y, u2, v2);
                mdraw(x, y);
        } else if (cmline(c, xconv(u1), yconv(v1)) == 0)
                mdraw(xconv(u2), yconv(v2));
}


int
cmline(                 /* start curve line in meta coords */
        int  c,
        int  x,
        int y
)
{
        int  lw, lt, col;
        register VARIABLE  *cv;

        cv = cparam[c];
        if (cv[CLINTYPE].flags & DEFINED)
                lt = varvalue(cv[CLINTYPE].name);
        else
                lt = DEFLINTYPE;
        if (lt-- <= 0)
                return(-1);
        if (cv[CTHICK].flags & DEFINED)
                lw = varvalue(cv[CTHICK].name);
        else
                lw = DEFTHICK;
        if (lw-- <= 0)
                return(-1);
        if (cv[CCOLOR].flags & DEFINED)
                col = varvalue(cv[CCOLOR].name);
        else
                col = DEFCOLOR;
        if (col-- <= 0)
                return(-1);
        mline(x, y, lt, lw, col);
        return(0);
}


void
csymbol(                /* plot curve symbol */
        int  c,
        double  u,
        double v
)
{
        int  x, y;
        
        if (period > FTINY) {
                pconv(&x, &y, u, v);
                cmsymbol(c, x, y);
        } else
                cmsymbol(c, xconv(u), yconv(v));
}


void
cmsymbol(               /* print curve symbol in meta coords */
        int  c,
        int  x,
        int y
)
{
        int  col, ss;
        register VARIABLE  *cv;

        cv = cparam[c];
        if (!(cv[CSYMTYPE].flags & DEFINED))
                return;
        if (cv[CSYMSIZE].flags & DEFINED)
                ss = varvalue(cv[CSYMSIZE].name);
        else
                ss = DEFSYMSIZE;
        if (ss <= 0)
                return;
        if (cv[CCOLOR].flags & DEFINED)
                col = varvalue(cv[CCOLOR].name);
        else
                col = DEFCOLOR;
        if (col-- <= 0)
                return;
        msegment(x-ss,y-ss,x+ss,y+ss,
                        cv[CSYMTYPE].v.s,'r',0,col);
}


int
inbounds(                       /* determine if x and y are within gbounds */
        double  x,
        double y
)
{
        if (x < xbounds.min || x > xbounds.max)
                return(0);
        if (y < ybounds.min || y > ybounds.max)
                return(0);
        return(1);
}
Revision:	1.2
Committed:	Sat Nov 15 02:13:37 2003 UTC (21 years, 11 months ago) by schorsch
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad5R4, rad5R2, rad5R3, rad5R0, rad5R1, rad4R2, rad3R7P2, rad3R7P1, rad6R0, rad4R1, rad4R0, rad3R6, rad3R6P1, rad3R8, rad3R9, rad4R2P1, rad4R2P2, HEAD
Changes since 1.1:	+130 -57 lines
Log Message:	Continued ANSIfication, and reduced other compile warnings.
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: mgraph.c,v 1.1 2003/02/22 02:07:26 greg Exp $";
3	#endif
4	/*
5	* mgraph.c - routines for plotting graphs from variables.
6	*
7	* 6/23/86
8	*
9	* Greg Ward Larson
10	*/
11
12	#include <stdio.h>
13	#include <string.h>
14
15	#include "meta.h"
16	#include "mgvars.h"
17	#include "mgraph.h"
18
19	extern char progname; / argv[0] */
20
21	extern double goodstep(), floor(), ceil(), sin(), cos();
22
23	static BOUNDS xbounds, ybounds; /* the boundaries for the graph */
24
25	static double period = DEFPERIOD; /* period for polar plot */
26
27	static double axbegin, axsize; /* the mapped x axis boundaries */
28	static double aybegin, aysize; /* the mapped y axis boundaries */
29
30	static int npltbl[MAXCUR]; /* plottable points per curve */
31
32	static double lastx, lasty; /* last curve postion */
33	static int nplottable; /* number of plottable points */
34	static int nplotted; /* number of plotted points */
35
36	static void getbounds(void);
37	static void polaraxis(void);
38	static void makeaxis(void);
39	static void plotcurves(void);
40	static void cartaxis(void);
41	static void stretchbounds(int c, double x, double y);
42	static void boxstring(int xmin, int ymin, int xmax, int ymax,
43	char *s, int d, int width, int color);
44	static void drawcircle(int x, int y, int r, int typ, int wid, int col);
45	static int rconv(double r);
46	static int xconv(double x);
47	static int yconv(double y);
48	static void csymbol(int c, double u, double v);
49	static int cmline(int c, int x, int y);
50	static void cmsymbol(int c, int x, int y);
51	static int inbounds(double x, double y);
52	static void climline(int c, double x, double y, double xout, double yout);
53	static void nextpoint(register int c, double x, double y);
54	static void cline(int c, double u1, double v1, double u2, double v2);
55
56
57	void
58	mgraph(void) /* plot the current graph */
59	{
60	/* load the symbol file */
61	if (gparam[SYMFILE].flags & DEFINED)
62	minclude(gparam[SYMFILE].v.s);
63	/* check for polar plot */
64	if (gparam[PERIOD].flags & DEFINED)
65	period = varvalue(gparam[PERIOD].name);
66
67	getbounds(); /* get the boundaries */
68	makeaxis(); /* draw the coordinate axis */
69	plotcurves(); /* plot the curves */
70
71	mendpage(); /* advance page */
72	}
73
74
75	void
76	getbounds(void) /* compute the boundaries */
77	{
78	int i;
79
80	xbounds.min = gparam[XMIN].flags & DEFINED ?
81	varvalue(gparam[XMIN].name) - FTINY :
82	FHUGE ;
83	xbounds.max = gparam[XMAX].flags & DEFINED ?
84	varvalue(gparam[XMAX].name) + FTINY :
85	-FHUGE ;
86	ybounds.min = gparam[YMIN].flags & DEFINED ?
87	varvalue(gparam[YMIN].name) - FTINY :
88	FHUGE ;
89	ybounds.max = gparam[YMAX].flags & DEFINED ?
90	varvalue(gparam[YMAX].name) + FTINY :
91	-FHUGE ;
92
93	nplottable = 0;
94	for (i = 0; i < MAXCUR; i++) {
95	npltbl[i] = 0;
96	mgcurve(i, stretchbounds);
97	nplottable += npltbl[i];
98	}
99	if (nplottable == 0) {
100	fprintf(stderr, "%s: no plottable data\n", progname);
101	quit(1);
102	}
103
104	xbounds.step = gparam[XSTEP].flags & DEFINED ?
105	varvalue(gparam[XSTEP].name) :
106	period > FTINY ?
107	DEFPLSTEP*period :
108	goodstep(xbounds.max - xbounds.min) ;
109	if (!(gparam[XMIN].flags & DEFINED))
110	xbounds.min = floor(xbounds.min/xbounds.step) *
111	xbounds.step;
112	if (!(gparam[XMAX].flags & DEFINED))
113	xbounds.max = ceil(xbounds.max/xbounds.step) *
114	xbounds.step;
115	ybounds.step = gparam[YSTEP].flags & DEFINED ?
116	varvalue(gparam[YSTEP].name) :
117	period > FTINY ?
118	goodstep((ybounds.max - ybounds.min)*1.75) :
119	goodstep(ybounds.max - ybounds.min) ;
120	if (!(gparam[YMIN].flags & DEFINED))
121	ybounds.min = floor(ybounds.min/ybounds.step) *
122	ybounds.step;
123	if (!(gparam[YMAX].flags & DEFINED))
124	ybounds.max = ceil(ybounds.max/ybounds.step) *
125	ybounds.step;
126	if (gparam[XMAP].flags & DEFINED) {
127	axbegin = funvalue(gparam[XMAP].name, 1, &xbounds.min);
128	axsize = funvalue(gparam[XMAP].name, 1, &xbounds.max);
129	axsize -= axbegin;
130	} else {
131	axbegin = xbounds.min;
132	axsize = xbounds.max;
133	axsize -= axbegin;
134	}
135	if (gparam[YMAP].flags & DEFINED) {
136	aybegin = funvalue(gparam[YMAP].name, 1, &ybounds.min);
137	aysize = funvalue(gparam[YMAP].name, 1, &ybounds.max);
138	aysize -= aybegin;
139	} else {
140	aybegin = ybounds.min;
141	aysize = ybounds.max;
142	aysize -= aybegin;
143	}
144	}
145
146
147	void
148	makeaxis(void) /* draw the coordinate axis */
149	{
150	char stmp[64];
151
152	if (period > FTINY)
153	polaraxis();
154	else
155	cartaxis();
156	/* x axis label */
157	if (gparam[XLABEL].flags & DEFINED)
158	boxstring(XL_L,XL_D,XL_R,XL_U,gparam[XLABEL].v.s,'r',0,0);
159	/* x mapping */
160	if (gparam[XMAP].flags & DEFINED) {
161	mgtoa(stmp, &gparam[XMAP]);
162	boxstring(XM_L,XM_D,XM_R,XM_U,stmp,'r',0,0);
163	}
164	/* y axis label */
165	if (gparam[YLABEL].flags & DEFINED)
166	boxstring(YL_L,YL_D,YL_R,YL_U,gparam[YLABEL].v.s,'u',0,0);
167	/* y mapping */
168	if (gparam[YMAP].flags & DEFINED) {
169	mgtoa(stmp, &gparam[YMAP]);
170	boxstring(YM_L,YM_D,YM_R,YM_U,stmp,'u',0,0);
171	}
172	/* title */
173	if (gparam[TITLE].flags & DEFINED)
174	boxstring(TI_L,TI_D,TI_R,TI_U,gparam[TITLE].v.s,'r',2,0);
175	/* subtitle */
176	if (gparam[SUBTITLE].flags & DEFINED)
177	boxstring(ST_L,ST_D,ST_R,ST_U,gparam[SUBTITLE].v.s,'r',1,0);
178	/* legend */
179	if (gparam[LEGEND].flags & DEFINED)
180	mtext(LT_X, LT_Y, gparam[LEGEND].v.s, CPI, 0);
181	}
182
183
184	void
185	polaraxis(void) /* print polar coordinate axis */
186	{
187	int lw, tstyle, t0, t1;
188	double d, d1, ybeg;
189	char stmp[64], fmt, goodformat();
190	/* get tick style */
191	if (gparam[TSTYLE].flags & DEFINED)
192	tstyle = varvalue(gparam[TSTYLE].name) + 0.5;
193	else
194	tstyle = DEFTSTYLE;
195	/* start of numbering */
196	ybeg = ceil(ybounds.min/ybounds.step)*ybounds.step;
197	/* theta (x) numbering */
198	fmt = goodformat(xbounds.step);
199	for (d = 0.0; d < period-FTINY; d += xbounds.step) {
200	sprintf(stmp, fmt, d);
201	d1 = d(2PI)/period;
202	t0 = TN_X + TN_R*cos(d1) + .5;
203	if (t0 < TN_X)
204	t0 -= strlen(stmp)*CWID;
205	mtext(t0,(int)(TN_Y+TN_R*sin(d1)+.5),stmp,CPI,0);
206	}
207	/* radius (y) numbering */
208	fmt = goodformat(ybounds.step);
209	lw = PL_R+RN_S;
210	for (d = ybeg; d <= ybounds.max+FTINY; d += ybounds.step) {
211	t0 = rconv(d);
212	if (t0 >= lw+RN_S \|\| t0 <= lw-RN_S) {
213	sprintf(stmp, fmt, d);
214	mtext(RN_X+t0-strlen(stmp)*(CWID/2),RN_Y,stmp,CPI,0);
215	lw = t0;
216	}
217	}
218	/* frame */
219	if (gparam[FTHICK].flags & DEFINED)
220	lw = varvalue(gparam[FTHICK].name) + 0.5;
221	else
222	lw = DEFFTHICK;
223	if (lw-- > 0) {
224	drawcircle(PL_X,PL_Y,PL_R,0,lw,0);
225	switch (tstyle) {
226	case 1: /* outside */
227	t0 = 0; t1 = TLEN; break;
228	case 2: /* inside */
229	t0 = TLEN; t1 = 0; break;
230	case 3: /* accross */
231	t0 = TLEN/2; t1 = TLEN/2; break;
232	default: /* none */
233	t0 = t1 = 0; break;
234	}
235	if (t0 + t1) {
236	for (d = 0.0; d < 2*PI-FTINY;
237	d += xbounds.step(2PI)/period) {
238	mline((int)(PL_X+(PL_R-t0)*cos(d)+.5),
239	(int)(PL_Y+(PL_R-t0)*sin(d)+.5),
240	0, lw, 0);
241	mdraw((int)(PL_X+(PL_R+t1)*cos(d)+.5),
242	(int)(PL_Y+(PL_R+t1)*sin(d)+.5));
243	}
244	}
245	}
246	/* origin */
247	if (gparam[OTHICK].flags & DEFINED)
248	lw = varvalue(gparam[OTHICK].name) + 0.5;
249	else
250	lw = DEFOTHICK;
251	if (lw-- > 0) {
252	mline(PL_X-PL_R,PL_Y,0,lw,0);
253	mdraw(PL_X+PL_R,PL_Y);
254	mline(PL_X,PL_Y-PL_R,0,lw,0);
255	mdraw(PL_X,PL_Y+PL_R);
256	if (tstyle > 0)
257	for (d = ybeg; d <= ybounds.max+FTINY;
258	d += ybounds.step) {
259	t0 = rconv(d);
260	mline(PL_X+t0,PL_Y-TLEN/2,0,lw,0);
261	mdraw(PL_X+t0,PL_Y+TLEN/2);
262	mline(PL_X-TLEN/2,PL_Y+t0,0,lw,0);
263	mdraw(PL_X+TLEN/2,PL_Y+t0);
264	mline(PL_X-t0,PL_Y-TLEN/2,0,lw,0);
265	mdraw(PL_X-t0,PL_Y+TLEN/2);
266	mline(PL_X-TLEN/2,PL_Y-t0,0,lw,0);
267	mdraw(PL_X+TLEN/2,PL_Y-t0);
268	}
269	}
270	/* grid */
271	if (gparam[GRID].flags & DEFINED)
272	lw = varvalue(gparam[GRID].name);
273	else
274	lw = DEFGRID;
275	if (lw-- > 0) {
276	for (d = 0.0; d < PI-FTINY; d += xbounds.step(2PI)/period) {
277	mline((int)(PL_X+PL_R*cos(d)+.5),
278	(int)(PL_Y+PL_R*sin(d)+.5),2,0,0);
279	mdraw((int)(PL_X-PL_R*cos(d)+.5),
280	(int)(PL_Y-PL_R*sin(d)+.5));
281	}
282	for (d = ybeg; d <= ybounds.max + FTINY; d += ybounds.step)
283	drawcircle(PL_X,PL_Y,rconv(d),2,0,0);
284	}
285	}
286
287	void
288	cartaxis(void) /* print Cartesian coordinate axis */
289	{
290	int lw, t0, t1, tstyle;
291	double d, xbeg, ybeg;
292	char stmp[64], fmt, goodformat();
293	register int i;
294	/* get tick style */
295	if (gparam[TSTYLE].flags & DEFINED)
296	tstyle = varvalue(gparam[TSTYLE].name) + 0.5;
297	else
298	tstyle = DEFTSTYLE;
299	/* start of numbering */
300	xbeg = ceil(xbounds.min/xbounds.step)*xbounds.step;
301	ybeg = ceil(ybounds.min/ybounds.step)*ybounds.step;
302
303	/* x numbering */
304	fmt = goodformat(xbounds.step);
305	lw = 2*AX_L-AX_R;
306	for (d = xbeg;
307	d <= xbounds.max + FTINY;
308	d += xbounds.step)
309	if ((i = xconv(d)) >= lw+XN_S \|\| i <= lw-XN_S) {
310	sprintf(stmp, fmt, d);
311	mtext(i-strlen(stmp)*(CWID/2)+XN_X,XN_Y,stmp,CPI,0);
312	lw = i;
313	}
314	/* y numbering */
315	fmt = goodformat(ybounds.step);
316	lw = 2*AX_D-AX_U;
317	for (d = ybeg;
318	d <= ybounds.max + FTINY;
319	d += ybounds.step)
320	if ((i = yconv(d)) >= lw+YN_S \|\| i <= lw-YN_S) {
321	sprintf(stmp, fmt, d);
322	mtext(YN_X-strlen(stmp)*CWID,i+YN_Y,stmp,CPI,0);
323	lw = i;
324	}
325	/* frame */
326	if (gparam[FTHICK].flags & DEFINED)
327	lw = varvalue(gparam[FTHICK].name) + 0.5;
328	else
329	lw = DEFFTHICK;
330	if (lw-- > 0) {
331	mline(AX_L,AX_D,0,lw,0);
332	mdraw(AX_R,AX_D);
333	mdraw(AX_R,AX_U);
334	mdraw(AX_L,AX_U);
335	mdraw(AX_L,AX_D);
336	switch (tstyle) {
337	case 1: /* outside */
338	t0 = 0; t1 = TLEN; break;
339	case 2: /* inside */
340	t0 = TLEN; t1 = 0; break;
341	case 3: /* accross */
342	t0 = TLEN/2; t1 = TLEN/2; break;
343	default: /* none */
344	t0 = t1 = 0; break;
345	}
346	if (t0 + t1) {
347	for (d = xbeg;
348	d <= xbounds.max + FTINY;
349	d += xbounds.step) {
350	i = xconv(d);
351	mline(i,AX_D+t0,0,lw,0);
352	mdraw(i,AX_D-t1);
353	mline(i,AX_U-t0,0,lw,0);
354	mdraw(i,AX_U+t1);
355	}
356	for (d = ybeg;
357	d <= ybounds.max + FTINY;
358	d += ybounds.step) {
359	i = yconv(d);
360	mline(AX_L+t0,i,0,lw,0);
361	mdraw(AX_L-t1,i);
362	mline(AX_R-t0,i,0,lw,0);
363	mdraw(AX_R+t1,i);
364	}
365	}
366	}
367	/* origin */
368	if (gparam[OTHICK].flags & DEFINED)
369	lw = varvalue(gparam[OTHICK].name) + 0.5;
370	else
371	lw = DEFOTHICK;
372	if (lw-- > 0) {
373	i = yconv(0.0);
374	if (i >= AX_D && i <= AX_U) {
375	mline(AX_L,i,0,lw,0);
376	mdraw(AX_R,i);
377	if (tstyle > 0)
378	for (d = xbeg; d <= xbounds.max+FTINY;
379	d += xbounds.step) {
380	mline(xconv(d),i+TLEN/2,0,lw,0);
381	mdraw(xconv(d),i-TLEN/2);
382	}
383	}
384	i = xconv(0.0);
385	if (i >= AX_L && i <= AX_R) {
386	mline(i,AX_D,0,lw,0);
387	mdraw(i,AX_U);
388	if (tstyle > 0)
389	for (d = ybeg; d <= ybounds.max+FTINY;
390	d += ybounds.step) {
391	mline(i+TLEN/2,yconv(d),0,lw,0);
392	mdraw(i-TLEN/2,yconv(d));
393	}
394	}
395	}
396	/* grid */
397	if (gparam[GRID].flags & DEFINED)
398	lw = varvalue(gparam[GRID].name);
399	else
400	lw = DEFGRID;
401	if (lw-- > 0) {
402	for (d = xbeg;
403	d <= xbounds.max + FTINY;
404	d += xbounds.step) {
405	i = xconv(d);
406	mline(i,AX_D,2,0,0);
407	mdraw(i,AX_U);
408	}
409	for (d = ybeg;
410	d <= ybounds.max + FTINY;
411	d += ybounds.step) {
412	i = yconv(d);
413	mline(AX_L,i,2,0,0);
414	mdraw(AX_R,i);
415	}
416	}
417	}
418
419	void
420	plotcurves(void) /* plot the curves */
421	{
422	int i, j, k;
423
424	for (i = 0; i < MAXCUR; i++) {
425	nplottable = nplotted = 0;
426	lastx = FHUGE;
427	if (mgcurve(i, nextpoint) > 0 &&
428	cparam[i][CLABEL].flags & DEFINED) {
429	j = (LE_U-LE_D)/MAXCUR;
430	k = LE_U - i*j;
431	mtext(LE_L+(LE_R-LE_L)/8,k+j/3,
432	cparam[i][CLABEL].v.s,CPI,0);
433	cmsymbol(i,LE_L,k);
434	if (cmline(i,LE_L,k) == 0)
435	mdraw(LE_R-(LE_R-LE_L)/4,k);
436	}
437	}
438	}
439
440	void
441	nextpoint( /* plot the next point for c */
442	register int c,
443	double x,
444	double y
445	)
446	{
447	if (inbounds(x, y)) {
448
449	if (!(cparam[c][CNPOINTS].flags & DEFINED) \|\|
450	nplotted * npltbl[c] <= nplottable *
451	(int)varvalue(cparam[c][CNPOINTS].name) ) {
452	csymbol(c, x, y);
453	nplotted++;
454	}
455	nplottable++;
456	if (lastx != FHUGE)
457	climline(c, x, y, lastx, lasty);
458
459	} else if (inbounds(lastx, lasty)) {
460
461	climline(c, lastx, lasty, x, y);
462
463	}
464	lastx = x;
465	lasty = y;
466	}
467
468
469	void
470	stretchbounds( /* stretch our boundaries */
471	int c,
472	double x,
473	double y
474	)
475	{
476	if (gparam[XMIN].flags & DEFINED &&
477	x < xbounds.min)
478	return;
479	if (gparam[XMAX].flags & DEFINED &&
480	x > xbounds.max)
481	return;
482	if (gparam[YMIN].flags & DEFINED &&
483	y < ybounds.min)
484	return;
485	if (gparam[YMAX].flags & DEFINED &&
486	y > ybounds.max)
487	return;
488
489	if (x < xbounds.min)
490	xbounds.min = x;
491	if (x > xbounds.max)
492	xbounds.max = x;
493	if (y < ybounds.min)
494	ybounds.min = y;
495	if (y > ybounds.max)
496	ybounds.max = y;
497
498	npltbl[c]++;
499	}
500
501
502	#define exp10(x) exp((x)*2.3025850929940456)
503
504	double
505	goodstep( /* determine a good step for the interval */
506	double interval
507	)
508	{
509	static int steps[] = {50, 20, 10, 5, 2, 1};
510	double fact, exp(), log10(), floor();
511	int i;
512
513	if (interval <= FTINY)
514	return(1.0);
515	fact = exp10(floor(log10(interval)))/10;
516	interval /= fact * MINDIVS;
517	for (i = 0; interval < steps[i]; i++)
518	;
519	return(steps[i] * fact);
520	}
521
522	#undef exp10
523
524
525	int
526	xconv( /* convert x to meta coords */
527	double x
528	)
529	{
530	if (gparam[XMAP].flags & DEFINED)
531	x = funvalue(gparam[XMAP].name, 1, &x);
532	x = (x - axbegin)/axsize;
533	return( AX_L + (int)(x*(AX_R-AX_L)) );
534	}
535
536
537	int
538	yconv( /* convert y to meta coords */
539	double y
540	)
541	{
542	if (gparam[YMAP].flags & DEFINED)
543	y = funvalue(gparam[YMAP].name, 1, &y);
544	y = (y - aybegin)/aysize;
545	return( AX_D + (int)(y*(AX_U-AX_D)) );
546	}
547
548
549	void
550	pconv( /* convert theta and radius to meta coords */
551	int *xp,
552	int *yp,
553	double t,
554	double r
555	)
556	{
557	t = (2.PI)/period;
558	r = rconv(r);
559	xp = rcos(t) + (PL_X+.5);
560	yp = rsin(t) + (PL_Y+.5);
561	}
562
563
564	int
565	rconv( /* convert radius to meta coords */
566	double r
567	)
568	{
569	if (gparam[YMAP].flags & DEFINED)
570	r = funvalue(gparam[YMAP].name, 1, &r);
571
572	return((r - aybegin)*PL_R/aysize + .5);
573	}
574
575
576	void
577	boxstring( /* put string in box */
578	int xmin,
579	int ymin,
580	int xmax,
581	int ymax,
582	char *s,
583	int d,
584	int width,
585	int color
586	)
587	{
588	register long size;
589
590	if (d == 'u' \|\| d == 'd') { /* up or down */
591	size = strlen(s)*(xmax-xmin)/ASPECT;
592	size -= ymax-ymin;
593	size /= 2;
594	if (size < 0) { /* center */
595	ymin -= size;
596	ymax += size;
597	}
598	} else { /* left or right */
599	size = strlen(s)*(ymax-ymin)/ASPECT;
600	size -= xmax-xmin;
601	size /= 2;
602	if (size < 0) { /* center */
603	xmin -= size;
604	xmax += size;
605	}
606	}
607	mvstr(xmin, ymin, xmax, ymax, s, d, width, color); /* print */
608	}
609
610
611	char *
612	goodformat( /* return a suitable format string for d */
613	double d
614	)
615	{
616	static char *f[5] = {"%.0f", "%.1f", "%.2f", "%.3f", "%.4f"};
617	double floor();
618	register int i;
619
620	if (d < 0.0)
621	d = -d;
622	if (d > 1e-4 && d < 1e6)
623	for (i = 0; i < 5; i++) {
624	if (d - floor(d+FTINY) <= FTINY)
625	return(f[i]);
626	d *= 10.0;
627	}
628	return("%.1e");
629	}
630
631
632	void
633	drawcircle( /* draw a circle */
634	int x,
635	int y,
636	int r,
637	int typ,
638	int wid,
639	int col
640	)
641	{
642	double d;
643
644	if (r <= 0)
645	return;
646	mline(x+r, y, typ, wid, col);
647	for (d = 2PIPL_F; d <= 2PI+FTINY; d += 2PI*PL_F)
648	mdraw((int)(x+rcos(d)+.5), (int)(y+rsin(d)+.5));
649	}
650
651
652	void
653	climline( /* print line from/to out of bounds */
654	int c,
655	double x,
656	double y,
657	double xout,
658	double yout
659	)
660	{
661	for ( ; ; )
662	if (xout < xbounds.min) {
663	yout = y + (yout - y)*(xbounds.min - x)/(xout - x);
664	xout = xbounds.min;
665	} else if (yout < ybounds.min) {
666	xout = x + (xout - x)*(ybounds.min - y)/(yout - y);
667	yout = ybounds.min;
668	} else if (xout > xbounds.max) {
669	yout = y + (yout - y)*(xbounds.max - x)/(xout - x);
670	xout = xbounds.max;
671	} else if (yout > ybounds.max) {
672	xout = x + (xout - x)*(ybounds.max - y)/(yout - y);
673	yout = ybounds.max;
674	} else {
675	cline(c, x, y, xout, yout);
676	break;
677	}
678	}
679
680
681	void
682	cline( /* print a curve line */
683	int c,
684	double u1,
685	double v1,
686	double u2,
687	double v2
688	)
689	{
690	int x, y;
691	double ustep, vstep;
692
693	if (period > FTINY) { /* polar */
694	if (u1 > u2) {
695	ustep = u1; u1 = u2; u2 = ustep;
696	vstep = v1; v1 = v2; v2 = vstep;
697	}
698	pconv(&x, &y, u1, v1);
699	if (cmline(c, x, y) < 0)
700	return;
701	ustep = period*PL_F;
702	if (u2-u1 > ustep) {
703	vstep = ustep*(v2-v1)/(u2-u1);
704	while ((u1 += ustep) < u2) {
705	v1 += vstep;
706	pconv(&x, &y, u1, v1);
707	mdraw(x, y);
708	}
709	}
710	pconv(&x, &y, u2, v2);
711	mdraw(x, y);
712	} else if (cmline(c, xconv(u1), yconv(v1)) == 0)
713	mdraw(xconv(u2), yconv(v2));
714	}
715
716
717	int
718	cmline( /* start curve line in meta coords */
719	int c,
720	int x,
721	int y
722	)
723	{
724	int lw, lt, col;
725	register VARIABLE *cv;
726
727	cv = cparam[c];
728	if (cv[CLINTYPE].flags & DEFINED)
729	lt = varvalue(cv[CLINTYPE].name);
730	else
731	lt = DEFLINTYPE;
732	if (lt-- <= 0)
733	return(-1);
734	if (cv[CTHICK].flags & DEFINED)
735	lw = varvalue(cv[CTHICK].name);
736	else
737	lw = DEFTHICK;
738	if (lw-- <= 0)
739	return(-1);
740	if (cv[CCOLOR].flags & DEFINED)
741	col = varvalue(cv[CCOLOR].name);
742	else
743	col = DEFCOLOR;
744	if (col-- <= 0)
745	return(-1);
746	mline(x, y, lt, lw, col);
747	return(0);
748	}
749
750
751	void
752	csymbol( /* plot curve symbol */
753	int c,
754	double u,
755	double v
756	)
757	{
758	int x, y;
759
760	if (period > FTINY) {
761	pconv(&x, &y, u, v);
762	cmsymbol(c, x, y);
763	} else
764	cmsymbol(c, xconv(u), yconv(v));
765	}
766
767
768	void
769	cmsymbol( /* print curve symbol in meta coords */
770	int c,
771	int x,
772	int y
773	)
774	{
775	int col, ss;
776	register VARIABLE *cv;
777
778	cv = cparam[c];
779	if (!(cv[CSYMTYPE].flags & DEFINED))
780	return;
781	if (cv[CSYMSIZE].flags & DEFINED)
782	ss = varvalue(cv[CSYMSIZE].name);
783	else
784	ss = DEFSYMSIZE;
785	if (ss <= 0)
786	return;
787	if (cv[CCOLOR].flags & DEFINED)
788	col = varvalue(cv[CCOLOR].name);
789	else
790	col = DEFCOLOR;
791	if (col-- <= 0)
792	return;
793	msegment(x-ss,y-ss,x+ss,y+ss,
794	cv[CSYMTYPE].v.s,'r',0,col);
795	}
796
797
798	int
799	inbounds( /* determine if x and y are within gbounds */
800	double x,
801	double y
802	)
803	{
804	if (x < xbounds.min \|\| x > xbounds.max)
805	return(0);
806	if (y < ybounds.min \|\| y > ybounds.max)
807	return(0);
808	return(1);
809	}