cv/mgflib/context.c

/* Copyright (c) 1994 Regents of the University of California */

#ifndef lint
static char SCCSid[] = "$SunId$ LBL";
#endif

/*
 * Context handlers
 */

#include <stdio.h>
#include <math.h>
#include <string.h>
#include "parser.h"
#include "lookup.h"

                                /* default context values */
static C_COLOR          c_dfcolor = C_DEFCOLOR;
static C_MATERIAL       c_dfmaterial = C_DEFMATERIAL;
static C_VERTEX         c_dfvertex = C_DEFVERTEX;

                                /* the unnamed contexts */
static C_COLOR          c_uncolor = C_DEFCOLOR;
static C_MATERIAL       c_unmaterial = C_DEFMATERIAL;
static C_VERTEX         c_unvertex = C_DEFVERTEX;

                                /* the current contexts */
C_COLOR         *c_ccolor = &c_uncolor;
char            *c_ccname = NULL;
C_MATERIAL      *c_cmaterial = &c_unmaterial;
char            *c_cmname = NULL;
C_VERTEX        *c_cvertex = &c_unvertex;
char            *c_cvname = NULL;

static LUTAB    clr_tab = LU_SINIT(free,free);  /* color lookup table */
static LUTAB    mat_tab = LU_SINIT(free,free);  /* material lookup table */
static LUTAB    vtx_tab = LU_SINIT(free,free);  /* vertex lookup table */

                                /* CIE 1931 Standard Observer */
static C_COLOR  cie_xf = C_CIEX;
static C_COLOR  cie_yf = C_CIEY;
static C_COLOR  cie_zf = C_CIEZ;

static int      setspectrum();
static void     mixcolors();


int
c_hcolor(ac, av)                /* handle color entity */
int     ac;
register char   **av;
{
        double  w, wsum;
        register int    i;
        register LUENT  *lp;

        switch (mg_entity(av[0])) {
        case MG_E_COLOR:        /* get/set color context */
                if (ac > 4)
                        return(MG_EARGC);
                if (ac == 1) {          /* set unnamed color context */
                        c_uncolor = c_dfcolor;
                        c_ccolor = &c_uncolor;
                        c_ccname = NULL;
                        return(MG_OK);
                }
                lp = lu_find(&clr_tab, av[1]);  /* lookup context */
                if (lp == NULL)
                        return(MG_EMEM);
                c_ccolor = (C_COLOR *)lp->data;
                if (ac == 2) {          /* reestablish previous context */
                        if (c_ccolor == NULL)
                                return(MG_EUNDEF);
                        return(MG_OK);
                }
                if (av[2][0] != '=' || av[2][1])
                        return(MG_ETYPE);
                if (c_ccolor == NULL) { /* create new color context */
                        lp->key = (char *)malloc(strlen(av[1])+1);
                        if (lp->key == NULL)
                                return(MG_EMEM);
                        strcpy(lp->key, av[1]);
                        lp->data = (char *)malloc(sizeof(C_COLOR));
                        if (lp->data == NULL)
                                return(MG_EMEM);
                        c_ccolor = (C_COLOR *)lp->data;
                        c_ccolor->clock = 0;
                }
                c_ccname = lp->key;
                i = c_ccolor->clock;
                if (ac == 3) {          /* use default template */
                        *c_ccolor = c_dfcolor;
                        c_ccolor->clock = i + 1;
                        return(MG_OK);
                }
                lp = lu_find(&clr_tab, av[3]);  /* lookup template */
                if (lp == NULL)
                        return(MG_EMEM);
                if (lp->data == NULL)
                        return(MG_EUNDEF);
                *c_ccolor = *(C_COLOR *)lp->data;
                c_ccolor->clock = i + 1;
                return(MG_OK);
        case MG_E_CXY:          /* assign CIE XY value */
                if (ac != 3)
                        return(MG_EARGC);
                if (!isflt(av[1]) || !isflt(av[2]))
                        return(MG_ETYPE);
                c_ccolor->cx = atof(av[1]);
                c_ccolor->cy = atof(av[2]);
                c_ccolor->flags = C_CDXY|C_CSXY;
                if (c_ccolor->cx < 0. | c_ccolor->cy < 0. |
                                c_ccolor->cx + c_ccolor->cy > 1.)
                        return(MG_EILL);
                c_ccolor->clock++;
                return(MG_OK);
        case MG_E_CSPEC:        /* assign spectral values */
                if (ac < 5)
                        return(MG_EARGC);
                if (!isint(av[1]) || !isint(av[2]))
                        return(MG_ETYPE);
                return(setspectrum(c_ccolor, atoi(av[1]), atoi(av[2]),
                                ac-3, av+3));
        case MG_E_CMIX:         /* mix colors */
                if (ac < 5 || (ac-1)%2)
                        return(MG_EARGC);
                if (!isflt(av[1]))
                        return(MG_ETYPE);
                wsum = atof(av[1]);
                if (wsum < 0.)
                        return(MG_EILL);
                if ((lp = lu_find(&clr_tab, av[2])) == NULL)
                        return(MG_EMEM);
                if (lp->data == NULL)
                        return(MG_EUNDEF);
                *c_ccolor = *(C_COLOR *)lp->data;
                for (i = 3; i < ac; i += 2) {
                        if (!isflt(av[i]))
                                return(MG_ETYPE);
                        w = atof(av[i]);
                        if (w < 0.)
                                return(MG_EILL);
                        if ((lp = lu_find(&clr_tab, av[i+1])) == NULL)
                                return(MG_EMEM);
                        if (lp->data == NULL)
                                return(MG_EUNDEF);
                        mixcolors(c_ccolor, wsum, c_ccolor,
                                        w, (C_COLOR *)lp->data);
                        wsum += w;
                }
                c_ccolor->clock++;
                return(MG_OK);
        }
        return(MG_EUNK);
}


int
c_hmaterial(ac, av)             /* handle material entity */
int     ac;
register char   **av;
{
        int     i;
        register LUENT  *lp;

        switch (mg_entity(av[0])) {
        case MG_E_MATERIAL:     /* get/set material context */
                if (ac > 4)
                        return(MG_EARGC);
                if (ac == 1) {          /* set unnamed material context */
                        c_unmaterial = c_dfmaterial;
                        c_cmaterial = &c_unmaterial;
                        c_cmname = NULL;
                        return(MG_OK);
                }
                lp = lu_find(&mat_tab, av[1]);  /* lookup context */
                if (lp == NULL)
                        return(MG_EMEM);
                c_cmaterial = (C_MATERIAL *)lp->data;
                if (ac == 2) {          /* reestablish previous context */
                        if (c_cmaterial == NULL)
                                return(MG_EUNDEF);
                        return(MG_OK);
                }
                if (av[2][0] != '=' || av[2][1])
                        return(MG_ETYPE);
                if (c_cmaterial == NULL) {      /* create new material */
                        lp->key = (char *)malloc(strlen(av[1])+1);
                        if (lp->key == NULL)
                                return(MG_EMEM);
                        strcpy(lp->key, av[1]);
                        lp->data = (char *)malloc(sizeof(C_MATERIAL));
                        if (lp->data == NULL)
                                return(MG_EMEM);
                        c_cmaterial = (C_MATERIAL *)lp->data;
                        c_cmaterial->clock = 0;
                }
                c_cmname = lp->key;
                i = c_cmaterial->clock;
                if (ac == 3) {          /* use default template */
                        *c_cmaterial = c_dfmaterial;
                        c_cmaterial->clock = i + 1;
                        return(MG_OK);
                }
                lp = lu_find(&mat_tab, av[3]);  /* lookup template */
                if (lp == NULL)
                        return(MG_EMEM);
                if (lp->data == NULL)
                        return(MG_EUNDEF);
                *c_cmaterial = *(C_MATERIAL *)lp->data;
                c_cmaterial->clock = i + 1;
                return(MG_OK);
        case MG_E_RD:           /* set diffuse reflectance */
                if (ac != 2)
                        return(MG_EARGC);
                if (!isflt(av[1]))
                        return(MG_ETYPE);
                c_cmaterial->rd = atof(av[1]);
                if (c_cmaterial->rd < 0. | c_cmaterial->rd > 1.)
                        return(MG_EILL);
                c_cmaterial->rd_c = *c_ccolor;
                c_cmaterial->clock++;
                return(MG_OK);
        case MG_E_ED:           /* set diffuse emittance */
                if (ac != 2)
                        return(MG_EARGC);
                if (!isflt(av[1]))
                        return(MG_ETYPE);
                c_cmaterial->ed = atof(av[1]);
                if (c_cmaterial->ed < 0.)
                        return(MG_EILL);
                c_cmaterial->ed_c = *c_ccolor;
                c_cmaterial->clock++;
                return(MG_OK);
        case MG_E_TD:           /* set diffuse transmittance */
                if (ac != 2)
                        return(MG_EARGC);
                if (!isflt(av[1]))
                        return(MG_ETYPE);
                c_cmaterial->td = atof(av[1]);
                if (c_cmaterial->td < 0. | c_cmaterial->td > 1.)
                        return(MG_EILL);
                c_cmaterial->td_c = *c_ccolor;
                c_cmaterial->clock++;
                return(MG_OK);
        case MG_E_RS:           /* set specular reflectance */
                if (ac != 3)
                        return(MG_EARGC);
                if (!isflt(av[1]) || !isflt(av[2]))
                        return(MG_ETYPE);
                c_cmaterial->rs = atof(av[1]);
                c_cmaterial->rs_a = atof(av[2]);
                if (c_cmaterial->rs < 0. | c_cmaterial->rs > 1. |
                                c_cmaterial->rs_a < 0.)
                        return(MG_EILL);
                c_cmaterial->rs_c = *c_ccolor;
                c_cmaterial->clock++;
                return(MG_OK);
        case MG_E_TS:           /* set specular transmittance */
                if (ac != 3)
                        return(MG_EARGC);
                if (!isflt(av[1]) || !isflt(av[2]))
                        return(MG_ETYPE);
                c_cmaterial->ts = atof(av[1]);
                c_cmaterial->ts_a = atof(av[2]);
                if (c_cmaterial->ts < 0. | c_cmaterial->ts > 1. |
                                c_cmaterial->ts_a < 0.)
                        return(MG_EILL);
                c_cmaterial->ts_c = *c_ccolor;
                c_cmaterial->clock++;
                return(MG_OK);
        case MG_E_SIDES:        /* set number of sides */
                if (ac != 2)
                        return(MG_EARGC);
                if (!isint(av[1]))
                        return(MG_ETYPE);
                i = atoi(av[1]);
                if (i == 1)
                        c_cmaterial->sided = 1;
                else if (i == 2)
                        c_cmaterial->sided = 0;
                else
                        return(MG_EILL);
                c_cmaterial->clock++;
                return(MG_OK);
        }
        return(MG_EUNK);
}


int
c_hvertex(ac, av)               /* handle a vertex entity */
int     ac;
register char   **av;
{
        int     i;
        register LUENT  *lp;

        switch (mg_entity(av[0])) {
        case MG_E_VERTEX:       /* get/set vertex context */
                if (ac > 4)
                        return(MG_EARGC);
                if (ac == 1) {          /* set unnamed vertex context */
                        c_unvertex = c_dfvertex;
                        c_cvertex = &c_unvertex;
                        c_cvname = NULL;
                        return(MG_OK);
                }
                lp = lu_find(&vtx_tab, av[1]);  /* lookup context */
                if (lp == NULL)
                        return(MG_EMEM);
                c_cvertex = (C_VERTEX *)lp->data;
                if (ac == 2) {          /* reestablish previous context */
                        if (c_cvertex == NULL)
                                return(MG_EUNDEF);
                        return(MG_OK);
                }
                if (av[2][0] != '=' || av[2][1])
                        return(MG_ETYPE);
                if (c_cvertex == NULL) {        /* create new vertex context */
                        lp->key = (char *)malloc(strlen(av[1])+1);
                        if (lp->key == NULL)
                                return(MG_EMEM);
                        strcpy(lp->key, av[1]);
                        lp->data = (char *)malloc(sizeof(C_VERTEX));
                        if (lp->data == NULL)
                                return(MG_EMEM);
                        c_cvertex = (C_VERTEX *)lp->data;
                }
                c_cvname = lp->key;
                i = c_cvertex->clock;
                if (ac == 3) {          /* use default template */
                        *c_cvertex = c_dfvertex;
                        c_cvertex->clock = i + 1;
                        return(MG_OK);
                }
                lp = lu_find(&vtx_tab, av[3]);  /* lookup template */
                if (lp == NULL)
                        return(MG_EMEM);
                if (lp->data == NULL)
                        return(MG_EUNDEF);
                *c_cvertex = *(C_VERTEX *)lp->data;
                c_cvertex->clock = i + 1;
                return(MG_OK);
        case MG_E_POINT:        /* set point */
                if (ac != 4)
                        return(MG_EARGC);
                if (!isflt(av[1]) || !isflt(av[2]) || !isflt(av[3]))
                        return(MG_ETYPE);
                c_cvertex->p[0] = atof(av[1]);
                c_cvertex->p[1] = atof(av[2]);
                c_cvertex->p[2] = atof(av[3]);
                c_cvertex->clock++;
                return(MG_OK);
        case MG_E_NORMAL:       /* set normal */
                if (ac != 4)
                        return(MG_EARGC);
                if (!isflt(av[1]) || !isflt(av[2]) || !isflt(av[3]))
                        return(MG_ETYPE);
                c_cvertex->n[0] = atof(av[1]);
                c_cvertex->n[1] = atof(av[2]);
                c_cvertex->n[2] = atof(av[3]);
                (void)normalize(c_cvertex->n);
                c_cvertex->clock++;
                return(MG_OK);
        }
        return(MG_EUNK);
}


void
c_clearall()                    /* empty context tables */
{
        c_uncolor = c_dfcolor;
        c_ccolor = &c_uncolor;
        lu_done(&clr_tab);
        c_unmaterial = c_dfmaterial;
        c_cmaterial = &c_unmaterial;
        lu_done(&mat_tab);
        c_unvertex = c_dfvertex;
        c_cvertex = &c_unvertex;
        lu_done(&vtx_tab);
}


C_MATERIAL *
c_getmaterial(name)             /* get a named material */
char    *name;
{
        register LUENT  *lp;

        if ((lp = lu_find(&mat_tab, name)) == NULL)
                return(NULL);
        return((C_MATERIAL *)lp->data);
}


C_VERTEX *
c_getvert(name)                 /* get a named vertex */
char    *name;
{
        register LUENT  *lp;

        if ((lp = lu_find(&vtx_tab, name)) == NULL)
                return(NULL);
        return((C_VERTEX *)lp->data);
}


C_COLOR *
c_getcolor(name)                /* get a named color */
char    *name;
{
        register LUENT  *lp;

        if ((lp = lu_find(&clr_tab, name)) == NULL)
                return(NULL);
        return((C_COLOR *)lp->data);
}


int
c_isgrey(clr)                   /* check if color is grey */
register C_COLOR        *clr;
{
        if (!(clr->flags & (C_CSXY|C_CSSPEC)))
                return(1);              /* no settings == grey */
        c_ccvt(clr, C_CSXY);
        return(clr->cx >= .323 && clr->cx <= .343 &&
                        clr->cy >= .323 && clr->cy <= .343);
}


void
c_ccvt(clr, fl)                 /* convert color representations */
register C_COLOR        *clr;
int     fl;
{
        double  x, y, z;
        register int    i;

        if (clr->flags & fl)            /* already done */
                return;
        if (!(clr->flags & (C_CSXY|C_CSSPEC)))  /* nothing set! */
                *clr = c_dfcolor;
        else if (fl & C_CSXY) {         /* cspec -> cxy */
                x = y = z = 0.;
                for (i = 0; i < C_CNSS; i++) {
                        x += cie_xf.ssamp[i] * clr->ssamp[i];
                        y += cie_yf.ssamp[i] * clr->ssamp[i];
                        z += cie_zf.ssamp[i] * clr->ssamp[i];
                }
                z += x + y;
                clr->cx = x / z;
                clr->cy = y / z;
                clr->flags |= C_CSXY;
        } else {                        /* cxy -> cspec */
                z = (cie_xf.ssum + cie_yf.ssum + cie_zf.ssum) / 3.;
                x = clr->cx * z / cie_xf.ssum;
                y = clr->cy * z / cie_yf.ssum;
                z = (1. - clr->cx - clr->cy) * z / cie_zf.ssum;
                clr->ssum = 0;
                for (i = 0; i < C_CNSS; i++)
                        clr->ssum += clr->ssamp[i] =
                                        x * cie_xf.ssamp[i] +
                                        y * cie_yf.ssamp[i] +
                                        z * cie_zf.ssamp[i] ;
                clr->flags |= C_CSSPEC;
        }
}


static int
setspectrum(clr, wlmin, wlmax, ac, av)  /* convert a spectrum */
register C_COLOR        *clr;
int     wlmin, wlmax;
int     ac;
char    **av;
{
        double  scale;
        float   *va;
        register int    i;
        int     wl, pos;
        double  wl0, wlstep;

        if (wlmin < C_CMINWL || wlmin >= wlmax || wlmax > C_CMAXWL)
                return(MG_EILL);
        if ((va = (float *)malloc(ac*sizeof(float))) == NULL)
                return(MG_EMEM);
        scale = 0.;                     /* get values and maximum */
        for (i = 0; i < ac; i++) {
                if (!isflt(av[i]))
                        return(MG_ETYPE);
                va[i] = atof(av[i]);
                if (va[i] < 0.)
                        return(MG_EILL);
                if (va[i] > scale)
                        scale = va[i];
        }
        if (scale == 0.)
                return(MG_EILL);
        scale = C_CMAXV / scale;
        clr->ssum = 0;                  /* convert to our spacing */
        wl0 = wlmin;
        wlstep = (double)(wlmax - wlmin)/(ac-1);
        pos = 0;
        for (i = 0, wl = C_CMINWL; i < C_CNSS; i++, wl += C_CWLI)
                if (wl < wlmin || wl > wlmax)
                        clr->ssamp[i] = 0;
                else {
                        while (wl0 + wlstep < wl+FTINY) {
                                wl0 += wlstep;
                                pos++;
                        }
                        if (wl+FTINY >= wl0 && wl-FTINY <= wl0)
                                clr->ssamp[i] = scale*va[pos];
                        else            /* interpolate if necessary */
                                clr->ssamp[i] = scale / wlstep *
                                                ( va[pos]*(wl0+wlstep - wl) +
                                                        va[pos+1]*(wl - wl0) );
                        clr->ssum += clr->ssamp[i];
                }
        clr->flags = C_CDSPEC|C_CSSPEC;
        clr->clock++;
        free((MEM_PTR)va);
        return(MG_OK);
}


static void
mixcolors(cres, w1, c1, w2, c2) /* mix two colors according to weights given */
register C_COLOR        *cres, *c1, *c2;
double  w1, w2;
{
        double  scale;
        float   cmix[C_CNSS];
        register int    i;

        if ((c1->flags|c2->flags) & C_CDSPEC) {         /* spectral mixing */
                c_ccvt(c1, C_CSSPEC);
                c_ccvt(c2, C_CSSPEC);
                w1 /= (double)c1->ssum;
                w2 /= (double)c2->ssum;
                scale = 0.;
                for (i = 0; i < C_CNSS; i++) {
                        cmix[i] = w1*c1->ssamp[i] + w2*c2->ssamp[i];
                        if (cmix[i] > scale)
                                scale = cmix[i];
                }
                scale = C_CMAXV / scale;
                cres->ssum = 0;
                for (i = 0; i < C_CNSS; i++)
                        cres->ssum += cres->ssamp[i] = scale*cmix[i] + .5;
                cres->flags = C_CDSPEC|C_CSSPEC;
        } else {                                        /* CIE xy mixing */
                c_ccvt(c1, C_CSXY);
                c_ccvt(c2, C_CSXY);
                scale = 1. / (w1/c1->cy + w2/c2->cy);
                cres->cx = (c1->cx*w1/c1->cy + c2->cx*w2/c2->cy) * scale;
                cres->cy = (w1 + w2) * scale;
                cres->flags = C_CDXY|C_CSXY;
        }
}
Revision:	1.13
Committed:	Fri Jul 1 18:06:56 1994 UTC (29 years, 10 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 1.12:	+14 -0 lines
Log Message:	added "sides" entity for one- vs. two-sided surfaces
#	Content
1	/* Copyright (c) 1994 Regents of the University of California */
2
3	#ifndef lint
4	static char SCCSid[] = "$SunId$ LBL";
5	#endif
6
7	/*
8	* Context handlers
9	*/
10
11	#include <stdio.h>
12	#include <math.h>
13	#include <string.h>
14	#include "parser.h"
15	#include "lookup.h"
16
17	/* default context values */
18	static C_COLOR c_dfcolor = C_DEFCOLOR;
19	static C_MATERIAL c_dfmaterial = C_DEFMATERIAL;
20	static C_VERTEX c_dfvertex = C_DEFVERTEX;
21
22	/* the unnamed contexts */
23	static C_COLOR c_uncolor = C_DEFCOLOR;
24	static C_MATERIAL c_unmaterial = C_DEFMATERIAL;
25	static C_VERTEX c_unvertex = C_DEFVERTEX;
26
27	/* the current contexts */
28	C_COLOR *c_ccolor = &c_uncolor;
29	char *c_ccname = NULL;
30	C_MATERIAL *c_cmaterial = &c_unmaterial;
31	char *c_cmname = NULL;
32	C_VERTEX *c_cvertex = &c_unvertex;
33	char *c_cvname = NULL;
34
35	static LUTAB clr_tab = LU_SINIT(free,free); /* color lookup table */
36	static LUTAB mat_tab = LU_SINIT(free,free); /* material lookup table */
37	static LUTAB vtx_tab = LU_SINIT(free,free); /* vertex lookup table */
38
39	/* CIE 1931 Standard Observer */
40	static C_COLOR cie_xf = C_CIEX;
41	static C_COLOR cie_yf = C_CIEY;
42	static C_COLOR cie_zf = C_CIEZ;
43
44	static int setspectrum();
45	static void mixcolors();
46
47
48	int
49	c_hcolor(ac, av) /* handle color entity */
50	int ac;
51	register char **av;
52	{
53	double w, wsum;
54	register int i;
55	register LUENT *lp;
56
57	switch (mg_entity(av[0])) {
58	case MG_E_COLOR: /* get/set color context */
59	if (ac > 4)
60	return(MG_EARGC);
61	if (ac == 1) { /* set unnamed color context */
62	c_uncolor = c_dfcolor;
63	c_ccolor = &c_uncolor;
64	c_ccname = NULL;
65	return(MG_OK);
66	}
67	lp = lu_find(&clr_tab, av[1]); /* lookup context */
68	if (lp == NULL)
69	return(MG_EMEM);
70	c_ccolor = (C_COLOR *)lp->data;
71	if (ac == 2) { /* reestablish previous context */
72	if (c_ccolor == NULL)
73	return(MG_EUNDEF);
74	return(MG_OK);
75	}
76	if (av[2][0] != '=' \|\| av[2][1])
77	return(MG_ETYPE);
78	if (c_ccolor == NULL) { /* create new color context */
79	lp->key = (char *)malloc(strlen(av[1])+1);
80	if (lp->key == NULL)
81	return(MG_EMEM);
82	strcpy(lp->key, av[1]);
83	lp->data = (char *)malloc(sizeof(C_COLOR));
84	if (lp->data == NULL)
85	return(MG_EMEM);
86	c_ccolor = (C_COLOR *)lp->data;
87	c_ccolor->clock = 0;
88	}
89	c_ccname = lp->key;
90	i = c_ccolor->clock;
91	if (ac == 3) { /* use default template */
92	*c_ccolor = c_dfcolor;
93	c_ccolor->clock = i + 1;
94	return(MG_OK);
95	}
96	lp = lu_find(&clr_tab, av[3]); /* lookup template */
97	if (lp == NULL)
98	return(MG_EMEM);
99	if (lp->data == NULL)
100	return(MG_EUNDEF);
101	c_ccolor = (C_COLOR *)lp->data;
102	c_ccolor->clock = i + 1;
103	return(MG_OK);
104	case MG_E_CXY: /* assign CIE XY value */
105	if (ac != 3)
106	return(MG_EARGC);
107	if (!isflt(av[1]) \|\| !isflt(av[2]))
108	return(MG_ETYPE);
109	c_ccolor->cx = atof(av[1]);
110	c_ccolor->cy = atof(av[2]);
111	c_ccolor->flags = C_CDXY\|C_CSXY;
112	if (c_ccolor->cx < 0. \| c_ccolor->cy < 0. \|
113	c_ccolor->cx + c_ccolor->cy > 1.)
114	return(MG_EILL);
115	c_ccolor->clock++;
116	return(MG_OK);
117	case MG_E_CSPEC: /* assign spectral values */
118	if (ac < 5)
119	return(MG_EARGC);
120	if (!isint(av[1]) \|\| !isint(av[2]))
121	return(MG_ETYPE);
122	return(setspectrum(c_ccolor, atoi(av[1]), atoi(av[2]),
123	ac-3, av+3));
124	case MG_E_CMIX: /* mix colors */
125	if (ac < 5 \|\| (ac-1)%2)
126	return(MG_EARGC);
127	if (!isflt(av[1]))
128	return(MG_ETYPE);
129	wsum = atof(av[1]);
130	if (wsum < 0.)
131	return(MG_EILL);
132	if ((lp = lu_find(&clr_tab, av[2])) == NULL)
133	return(MG_EMEM);
134	if (lp->data == NULL)
135	return(MG_EUNDEF);
136	c_ccolor = (C_COLOR *)lp->data;
137	for (i = 3; i < ac; i += 2) {
138	if (!isflt(av[i]))
139	return(MG_ETYPE);
140	w = atof(av[i]);
141	if (w < 0.)
142	return(MG_EILL);
143	if ((lp = lu_find(&clr_tab, av[i+1])) == NULL)
144	return(MG_EMEM);
145	if (lp->data == NULL)
146	return(MG_EUNDEF);
147	mixcolors(c_ccolor, wsum, c_ccolor,
148	w, (C_COLOR *)lp->data);
149	wsum += w;
150	}
151	c_ccolor->clock++;
152	return(MG_OK);
153	}
154	return(MG_EUNK);
155	}
156
157
158	int
159	c_hmaterial(ac, av) /* handle material entity */
160	int ac;
161	register char **av;
162	{
163	int i;
164	register LUENT *lp;
165
166	switch (mg_entity(av[0])) {
167	case MG_E_MATERIAL: /* get/set material context */
168	if (ac > 4)
169	return(MG_EARGC);
170	if (ac == 1) { /* set unnamed material context */
171	c_unmaterial = c_dfmaterial;
172	c_cmaterial = &c_unmaterial;
173	c_cmname = NULL;
174	return(MG_OK);
175	}
176	lp = lu_find(&mat_tab, av[1]); /* lookup context */
177	if (lp == NULL)
178	return(MG_EMEM);
179	c_cmaterial = (C_MATERIAL *)lp->data;
180	if (ac == 2) { /* reestablish previous context */
181	if (c_cmaterial == NULL)
182	return(MG_EUNDEF);
183	return(MG_OK);
184	}
185	if (av[2][0] != '=' \|\| av[2][1])
186	return(MG_ETYPE);
187	if (c_cmaterial == NULL) { /* create new material */
188	lp->key = (char *)malloc(strlen(av[1])+1);
189	if (lp->key == NULL)
190	return(MG_EMEM);
191	strcpy(lp->key, av[1]);
192	lp->data = (char *)malloc(sizeof(C_MATERIAL));
193	if (lp->data == NULL)
194	return(MG_EMEM);
195	c_cmaterial = (C_MATERIAL *)lp->data;
196	c_cmaterial->clock = 0;
197	}
198	c_cmname = lp->key;
199	i = c_cmaterial->clock;
200	if (ac == 3) { /* use default template */
201	*c_cmaterial = c_dfmaterial;
202	c_cmaterial->clock = i + 1;
203	return(MG_OK);
204	}
205	lp = lu_find(&mat_tab, av[3]); /* lookup template */
206	if (lp == NULL)
207	return(MG_EMEM);
208	if (lp->data == NULL)
209	return(MG_EUNDEF);
210	c_cmaterial = (C_MATERIAL *)lp->data;
211	c_cmaterial->clock = i + 1;
212	return(MG_OK);
213	case MG_E_RD: /* set diffuse reflectance */
214	if (ac != 2)
215	return(MG_EARGC);
216	if (!isflt(av[1]))
217	return(MG_ETYPE);
218	c_cmaterial->rd = atof(av[1]);
219	if (c_cmaterial->rd < 0. \| c_cmaterial->rd > 1.)
220	return(MG_EILL);
221	c_cmaterial->rd_c = *c_ccolor;
222	c_cmaterial->clock++;
223	return(MG_OK);
224	case MG_E_ED: /* set diffuse emittance */
225	if (ac != 2)
226	return(MG_EARGC);
227	if (!isflt(av[1]))
228	return(MG_ETYPE);
229	c_cmaterial->ed = atof(av[1]);
230	if (c_cmaterial->ed < 0.)
231	return(MG_EILL);
232	c_cmaterial->ed_c = *c_ccolor;
233	c_cmaterial->clock++;
234	return(MG_OK);
235	case MG_E_TD: /* set diffuse transmittance */
236	if (ac != 2)
237	return(MG_EARGC);
238	if (!isflt(av[1]))
239	return(MG_ETYPE);
240	c_cmaterial->td = atof(av[1]);
241	if (c_cmaterial->td < 0. \| c_cmaterial->td > 1.)
242	return(MG_EILL);
243	c_cmaterial->td_c = *c_ccolor;
244	c_cmaterial->clock++;
245	return(MG_OK);
246	case MG_E_RS: /* set specular reflectance */
247	if (ac != 3)
248	return(MG_EARGC);
249	if (!isflt(av[1]) \|\| !isflt(av[2]))
250	return(MG_ETYPE);
251	c_cmaterial->rs = atof(av[1]);
252	c_cmaterial->rs_a = atof(av[2]);
253	if (c_cmaterial->rs < 0. \| c_cmaterial->rs > 1. \|
254	c_cmaterial->rs_a < 0.)
255	return(MG_EILL);
256	c_cmaterial->rs_c = *c_ccolor;
257	c_cmaterial->clock++;
258	return(MG_OK);
259	case MG_E_TS: /* set specular transmittance */
260	if (ac != 3)
261	return(MG_EARGC);
262	if (!isflt(av[1]) \|\| !isflt(av[2]))
263	return(MG_ETYPE);
264	c_cmaterial->ts = atof(av[1]);
265	c_cmaterial->ts_a = atof(av[2]);
266	if (c_cmaterial->ts < 0. \| c_cmaterial->ts > 1. \|
267	c_cmaterial->ts_a < 0.)
268	return(MG_EILL);
269	c_cmaterial->ts_c = *c_ccolor;
270	c_cmaterial->clock++;
271	return(MG_OK);
272	case MG_E_SIDES: /* set number of sides */
273	if (ac != 2)
274	return(MG_EARGC);
275	if (!isint(av[1]))
276	return(MG_ETYPE);
277	i = atoi(av[1]);
278	if (i == 1)
279	c_cmaterial->sided = 1;
280	else if (i == 2)
281	c_cmaterial->sided = 0;
282	else
283	return(MG_EILL);
284	c_cmaterial->clock++;
285	return(MG_OK);
286	}
287	return(MG_EUNK);
288	}
289
290
291	int
292	c_hvertex(ac, av) /* handle a vertex entity */
293	int ac;
294	register char **av;
295	{
296	int i;
297	register LUENT *lp;
298
299	switch (mg_entity(av[0])) {
300	case MG_E_VERTEX: /* get/set vertex context */
301	if (ac > 4)
302	return(MG_EARGC);
303	if (ac == 1) { /* set unnamed vertex context */
304	c_unvertex = c_dfvertex;
305	c_cvertex = &c_unvertex;
306	c_cvname = NULL;
307	return(MG_OK);
308	}
309	lp = lu_find(&vtx_tab, av[1]); /* lookup context */
310	if (lp == NULL)
311	return(MG_EMEM);
312	c_cvertex = (C_VERTEX *)lp->data;
313	if (ac == 2) { /* reestablish previous context */
314	if (c_cvertex == NULL)
315	return(MG_EUNDEF);
316	return(MG_OK);
317	}
318	if (av[2][0] != '=' \|\| av[2][1])
319	return(MG_ETYPE);
320	if (c_cvertex == NULL) { /* create new vertex context */
321	lp->key = (char *)malloc(strlen(av[1])+1);
322	if (lp->key == NULL)
323	return(MG_EMEM);
324	strcpy(lp->key, av[1]);
325	lp->data = (char *)malloc(sizeof(C_VERTEX));
326	if (lp->data == NULL)
327	return(MG_EMEM);
328	c_cvertex = (C_VERTEX *)lp->data;
329	}
330	c_cvname = lp->key;
331	i = c_cvertex->clock;
332	if (ac == 3) { /* use default template */
333	*c_cvertex = c_dfvertex;
334	c_cvertex->clock = i + 1;
335	return(MG_OK);
336	}
337	lp = lu_find(&vtx_tab, av[3]); /* lookup template */
338	if (lp == NULL)
339	return(MG_EMEM);
340	if (lp->data == NULL)
341	return(MG_EUNDEF);
342	c_cvertex = (C_VERTEX *)lp->data;
343	c_cvertex->clock = i + 1;
344	return(MG_OK);
345	case MG_E_POINT: /* set point */
346	if (ac != 4)
347	return(MG_EARGC);
348	if (!isflt(av[1]) \|\| !isflt(av[2]) \|\| !isflt(av[3]))
349	return(MG_ETYPE);
350	c_cvertex->p[0] = atof(av[1]);
351	c_cvertex->p[1] = atof(av[2]);
352	c_cvertex->p[2] = atof(av[3]);
353	c_cvertex->clock++;
354	return(MG_OK);
355	case MG_E_NORMAL: /* set normal */
356	if (ac != 4)
357	return(MG_EARGC);
358	if (!isflt(av[1]) \|\| !isflt(av[2]) \|\| !isflt(av[3]))
359	return(MG_ETYPE);
360	c_cvertex->n[0] = atof(av[1]);
361	c_cvertex->n[1] = atof(av[2]);
362	c_cvertex->n[2] = atof(av[3]);
363	(void)normalize(c_cvertex->n);
364	c_cvertex->clock++;
365	return(MG_OK);
366	}
367	return(MG_EUNK);
368	}
369
370
371	void
372	c_clearall() /* empty context tables */
373	{
374	c_uncolor = c_dfcolor;
375	c_ccolor = &c_uncolor;
376	lu_done(&clr_tab);
377	c_unmaterial = c_dfmaterial;
378	c_cmaterial = &c_unmaterial;
379	lu_done(&mat_tab);
380	c_unvertex = c_dfvertex;
381	c_cvertex = &c_unvertex;
382	lu_done(&vtx_tab);
383	}
384
385
386	C_MATERIAL *
387	c_getmaterial(name) /* get a named material */
388	char *name;
389	{
390	register LUENT *lp;
391
392	if ((lp = lu_find(&mat_tab, name)) == NULL)
393	return(NULL);
394	return((C_MATERIAL *)lp->data);
395	}
396
397
398	C_VERTEX *
399	c_getvert(name) /* get a named vertex */
400	char *name;
401	{
402	register LUENT *lp;
403
404	if ((lp = lu_find(&vtx_tab, name)) == NULL)
405	return(NULL);
406	return((C_VERTEX *)lp->data);
407	}
408
409
410	C_COLOR *
411	c_getcolor(name) /* get a named color */
412	char *name;
413	{
414	register LUENT *lp;
415
416	if ((lp = lu_find(&clr_tab, name)) == NULL)
417	return(NULL);
418	return((C_COLOR *)lp->data);
419	}
420
421
422	int
423	c_isgrey(clr) /* check if color is grey */
424	register C_COLOR *clr;
425	{
426	if (!(clr->flags & (C_CSXY\|C_CSSPEC)))
427	return(1); /* no settings == grey */
428	c_ccvt(clr, C_CSXY);
429	return(clr->cx >= .323 && clr->cx <= .343 &&
430	clr->cy >= .323 && clr->cy <= .343);
431	}
432
433
434	void
435	c_ccvt(clr, fl) /* convert color representations */
436	register C_COLOR *clr;
437	int fl;
438	{
439	double x, y, z;
440	register int i;
441
442	if (clr->flags & fl) /* already done */
443	return;
444	if (!(clr->flags & (C_CSXY\|C_CSSPEC))) /* nothing set! */
445	*clr = c_dfcolor;
446	else if (fl & C_CSXY) { /* cspec -> cxy */
447	x = y = z = 0.;
448	for (i = 0; i < C_CNSS; i++) {
449	x += cie_xf.ssamp[i] * clr->ssamp[i];
450	y += cie_yf.ssamp[i] * clr->ssamp[i];
451	z += cie_zf.ssamp[i] * clr->ssamp[i];
452	}
453	z += x + y;
454	clr->cx = x / z;
455	clr->cy = y / z;
456	clr->flags \|= C_CSXY;
457	} else { /* cxy -> cspec */
458	z = (cie_xf.ssum + cie_yf.ssum + cie_zf.ssum) / 3.;
459	x = clr->cx * z / cie_xf.ssum;
460	y = clr->cy * z / cie_yf.ssum;
461	z = (1. - clr->cx - clr->cy) * z / cie_zf.ssum;
462	clr->ssum = 0;
463	for (i = 0; i < C_CNSS; i++)
464	clr->ssum += clr->ssamp[i] =
465	x * cie_xf.ssamp[i] +
466	y * cie_yf.ssamp[i] +
467	z * cie_zf.ssamp[i] ;
468	clr->flags \|= C_CSSPEC;
469	}
470	}
471
472
473	static int
474	setspectrum(clr, wlmin, wlmax, ac, av) /* convert a spectrum */
475	register C_COLOR *clr;
476	int wlmin, wlmax;
477	int ac;
478	char **av;
479	{
480	double scale;
481	float *va;
482	register int i;
483	int wl, pos;
484	double wl0, wlstep;
485
486	if (wlmin < C_CMINWL \|\| wlmin >= wlmax \|\| wlmax > C_CMAXWL)
487	return(MG_EILL);
488	if ((va = (float )malloc(acsizeof(float))) == NULL)
489	return(MG_EMEM);
490	scale = 0.; /* get values and maximum */
491	for (i = 0; i < ac; i++) {
492	if (!isflt(av[i]))
493	return(MG_ETYPE);
494	va[i] = atof(av[i]);
495	if (va[i] < 0.)
496	return(MG_EILL);
497	if (va[i] > scale)
498	scale = va[i];
499	}
500	if (scale == 0.)
501	return(MG_EILL);
502	scale = C_CMAXV / scale;
503	clr->ssum = 0; /* convert to our spacing */
504	wl0 = wlmin;
505	wlstep = (double)(wlmax - wlmin)/(ac-1);
506	pos = 0;
507	for (i = 0, wl = C_CMINWL; i < C_CNSS; i++, wl += C_CWLI)
508	if (wl < wlmin \|\| wl > wlmax)
509	clr->ssamp[i] = 0;
510	else {
511	while (wl0 + wlstep < wl+FTINY) {
512	wl0 += wlstep;
513	pos++;
514	}
515	if (wl+FTINY >= wl0 && wl-FTINY <= wl0)
516	clr->ssamp[i] = scale*va[pos];
517	else /* interpolate if necessary */
518	clr->ssamp[i] = scale / wlstep *
519	( va[pos]*(wl0+wlstep - wl) +
520	va[pos+1]*(wl - wl0) );
521	clr->ssum += clr->ssamp[i];
522	}
523	clr->flags = C_CDSPEC\|C_CSSPEC;
524	clr->clock++;
525	free((MEM_PTR)va);
526	return(MG_OK);
527	}
528
529
530	static void
531	mixcolors(cres, w1, c1, w2, c2) /* mix two colors according to weights given */
532	register C_COLOR cres, c1, *c2;
533	double w1, w2;
534	{
535	double scale;
536	float cmix[C_CNSS];
537	register int i;
538
539	if ((c1->flags\|c2->flags) & C_CDSPEC) { /* spectral mixing */
540	c_ccvt(c1, C_CSSPEC);
541	c_ccvt(c2, C_CSSPEC);
542	w1 /= (double)c1->ssum;
543	w2 /= (double)c2->ssum;
544	scale = 0.;
545	for (i = 0; i < C_CNSS; i++) {
546	cmix[i] = w1c1->ssamp[i] + w2c2->ssamp[i];
547	if (cmix[i] > scale)
548	scale = cmix[i];
549	}
550	scale = C_CMAXV / scale;
551	cres->ssum = 0;
552	for (i = 0; i < C_CNSS; i++)
553	cres->ssum += cres->ssamp[i] = scale*cmix[i] + .5;
554	cres->flags = C_CDSPEC\|C_CSSPEC;
555	} else { /* CIE xy mixing */
556	c_ccvt(c1, C_CSXY);
557	c_ccvt(c2, C_CSXY);
558	scale = 1. / (w1/c1->cy + w2/c2->cy);
559	cres->cx = (c1->cxw1/c1->cy + c2->cxw2/c2->cy) * scale;
560	cres->cy = (w1 + w2) * scale;
561	cres->flags = C_CDXY\|C_CSXY;
562	}
563	}