src/common/mgf_context.c

#ifndef lint
static const char       RCSid[] = "$Id: context.c,v 1.30 2011/02/03 19:36:10 greg Exp $";
#endif
/*
 * Context handlers
 */

#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "mgf_parser.h"
#include "lookup.h"

                                /* default context values */
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 */

static int      setspectrum(C_COLOR *, double wlmin, double wlmax,
                                int ac, char **av);


int
c_hcolor(int ac, char **av)             /* handle color entity */
{
        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);
                }
                if (!isname(av[1]))
                        return(MG_EILL);
                lp = lu_find(&clr_tab, av[1]);  /* lookup context */
                if (lp == NULL)
                        return(MG_EMEM);
                c_ccname = lp->key;
                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_ccname = lp->key;
                        c_ccolor = (C_COLOR *)lp->data;
                        c_ccolor->clock = 0;
                        c_ccolor->client_data = NULL;
                }
                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 (!isflt(av[1]) | !isflt(av[2]))
                        return(MG_ETYPE);
                return(setspectrum(c_ccolor, atof(av[1]), atof(av[2]),
                                ac-3, av+3));
        case MG_E_CCT:          /* assign black body spectrum */
                if (ac != 2)
                        return(MG_EARGC);
                if (!isflt(av[1]))
                        return(MG_ETYPE);
                if (!c_bbtemp(c_ccolor, atof(av[1])))
                        return(MG_EILL);
                c_ccolor->clock++;
                return(MG_OK);
        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 ((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 ((lp = lu_find(&clr_tab, av[i+1])) == NULL)
                                return(MG_EMEM);
                        if (lp->data == NULL)
                                return(MG_EUNDEF);
                        c_cmix(c_ccolor, wsum, c_ccolor,
                                        w, (C_COLOR *)lp->data);
                        wsum += w;
                }
                if (wsum <= 0.)
                        return(MG_EILL);
                c_ccolor->clock++;
                return(MG_OK);
        }
        return(MG_EUNK);
}


int
c_hmaterial(int ac, char **av)          /* handle material entity */
{
        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);
                }
                if (!isname(av[1]))
                        return(MG_EILL);
                lp = lu_find(&mat_tab, av[1]);  /* lookup context */
                if (lp == NULL)
                        return(MG_EMEM);
                c_cmname = lp->key;
                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_cmname = lp->key;
                        c_cmaterial = (C_MATERIAL *)lp->data;
                        c_cmaterial->clock = 0;
                        c_cmaterial->client_data = NULL;
                }
                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_IR:           /* set index of refraction */
                if (ac != 3)
                        return(MG_EARGC);
                if (!isflt(av[1]) | !isflt(av[2]))
                        return(MG_ETYPE);
                c_cmaterial->nr = atof(av[1]);
                c_cmaterial->ni = atof(av[2]);
                if (c_cmaterial->nr <= FTINY)
                        return(MG_EILL);
                c_cmaterial->clock++;
                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(int ac, char **av)            /* handle a vertex entity */
{
        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);
                }
                if (!isname(av[1]))
                        return(MG_EILL);
                lp = lu_find(&vtx_tab, av[1]);  /* lookup context */
                if (lp == NULL)
                        return(MG_EMEM);
                c_cvname = lp->key;
                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_cvname = lp->key;
                        c_cvertex = (C_VERTEX *)lp->data;
                        c_cvertex->clock = 0;
                        c_cvertex->client_data = NULL;
                }
                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(void)                /* empty context tables */
{
        c_uncolor = c_dfcolor;
        c_ccolor = &c_uncolor;
        c_ccname = NULL;
        lu_done(&clr_tab);
        c_unmaterial = c_dfmaterial;
        c_cmaterial = &c_unmaterial;
        c_cmname = NULL;
        lu_done(&mat_tab);
        c_unvertex = c_dfvertex;
        c_cvertex = &c_unvertex;
        c_cvname = NULL;
        lu_done(&vtx_tab);
}


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

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


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

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


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

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


static int
setspectrum(            /* convert a spectrum */
        register C_COLOR        *clr,
        double  wlmin, 
        double  wlmax,
        int     ac,
        char    **av
)
{
        double  scale;
        float   va[C_CNSS];
        register int    i, pos;
        int     n, imax;
        int     wl;
        double  wl0, wlstep;
        double  boxpos, boxstep;
                                        /* check bounds */
        if ((wlmax <= C_CMINWL) | (wlmax <= wlmin) | (wlmin >= C_CMAXWL))
                return(MG_EILL);
        wlstep = (wlmax - wlmin)/(ac-1);
        while (wlmin < C_CMINWL) {
                wlmin += wlstep;
                ac--; av++;
        }
        while (wlmax > C_CMAXWL) {
                wlmax -= wlstep;
                ac--;
        }
        imax = ac;                      /* box filter if necessary */
        boxpos = 0;
        boxstep = 1;
        if (wlstep < C_CWLI) {
                imax = (wlmax - wlmin)/C_CWLI + (1-FTINY);
                boxpos = (wlmin - C_CMINWL)/C_CWLI;
                boxstep = wlstep/C_CWLI;
                wlstep = C_CWLI;
        }
        scale = 0.;                     /* get values and maximum */
        pos = 0;
        for (i = 0; i < imax; i++) {
                va[i] = 0.; n = 0;
                while (boxpos < i+.5 && pos < ac) {
                        if (!isflt(av[pos]))
                                return(MG_ETYPE);
                        va[i] += atof(av[pos++]);
                        n++;
                        boxpos += boxstep;
                }
                if (n > 1)
                        va[i] /= (double)n;
                if (va[i] > scale)
                        scale = va[i];
                else if (va[i] < -scale)
                        scale = -va[i];
        }
        if (scale <= FTINY)
                return(MG_EILL);
        scale = C_CMAXV / scale;
        clr->ssum = 0;                  /* convert to our spacing */
        wl0 = wlmin;
        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] + .5;
                        else            /* interpolate if necessary */
                                clr->ssamp[i] = .5 + 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++;
        return(MG_OK);
}
Revision:	3.1
Committed:	Fri Feb 18 00:40:25 2011 UTC (13 years, 2 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad4R1
Log Message:	Major code reorg, moving mgflib to common and introducing BSDF material
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: context.c,v 1.30 2011/02/03 19:36:10 greg Exp $";
3	#endif
4	/*
5	* Context handlers
6	*/
7
8	#include <stdio.h>
9	#include <stdlib.h>
10	#include <string.h>
11	#include "mgf_parser.h"
12	#include "lookup.h"
13
14	/* default context values */
15	static C_MATERIAL c_dfmaterial = C_DEFMATERIAL;
16	static C_VERTEX c_dfvertex = C_DEFVERTEX;
17
18	/* the unnamed contexts */
19	static C_COLOR c_uncolor = C_DEFCOLOR;
20	static C_MATERIAL c_unmaterial = C_DEFMATERIAL;
21	static C_VERTEX c_unvertex = C_DEFVERTEX;
22
23	/* the current contexts */
24	C_COLOR *c_ccolor = &c_uncolor;
25	char *c_ccname = NULL;
26	C_MATERIAL *c_cmaterial = &c_unmaterial;
27	char *c_cmname = NULL;
28	C_VERTEX *c_cvertex = &c_unvertex;
29	char *c_cvname = NULL;
30
31	static LUTAB clr_tab = LU_SINIT(free,free); /* color lookup table */
32	static LUTAB mat_tab = LU_SINIT(free,free); /* material lookup table */
33	static LUTAB vtx_tab = LU_SINIT(free,free); /* vertex lookup table */
34
35	static int setspectrum(C_COLOR *, double wlmin, double wlmax,
36	int ac, char **av);
37
38
39	int
40	c_hcolor(int ac, char *av) / handle color entity */
41	{
42	double w, wsum;
43	register int i;
44	register LUENT *lp;
45
46	switch (mg_entity(av[0])) {
47	case MG_E_COLOR: /* get/set color context */
48	if (ac > 4)
49	return(MG_EARGC);
50	if (ac == 1) { /* set unnamed color context */
51	c_uncolor = c_dfcolor;
52	c_ccolor = &c_uncolor;
53	c_ccname = NULL;
54	return(MG_OK);
55	}
56	if (!isname(av[1]))
57	return(MG_EILL);
58	lp = lu_find(&clr_tab, av[1]); /* lookup context */
59	if (lp == NULL)
60	return(MG_EMEM);
61	c_ccname = lp->key;
62	c_ccolor = (C_COLOR *)lp->data;
63	if (ac == 2) { /* reestablish previous context */
64	if (c_ccolor == NULL)
65	return(MG_EUNDEF);
66	return(MG_OK);
67	}
68	if (av[2][0] != '=' \|\| av[2][1])
69	return(MG_ETYPE);
70	if (c_ccolor == NULL) { /* create new color context */
71	lp->key = (char *)malloc(strlen(av[1])+1);
72	if (lp->key == NULL)
73	return(MG_EMEM);
74	strcpy(lp->key, av[1]);
75	lp->data = (char *)malloc(sizeof(C_COLOR));
76	if (lp->data == NULL)
77	return(MG_EMEM);
78	c_ccname = lp->key;
79	c_ccolor = (C_COLOR *)lp->data;
80	c_ccolor->clock = 0;
81	c_ccolor->client_data = NULL;
82	}
83	i = c_ccolor->clock;
84	if (ac == 3) { /* use default template */
85	*c_ccolor = c_dfcolor;
86	c_ccolor->clock = i + 1;
87	return(MG_OK);
88	}
89	lp = lu_find(&clr_tab, av[3]); /* lookup template */
90	if (lp == NULL)
91	return(MG_EMEM);
92	if (lp->data == NULL)
93	return(MG_EUNDEF);
94	c_ccolor = (C_COLOR *)lp->data;
95	c_ccolor->clock = i + 1;
96	return(MG_OK);
97	case MG_E_CXY: /* assign CIE XY value */
98	if (ac != 3)
99	return(MG_EARGC);
100	if (!isflt(av[1]) \| !isflt(av[2]))
101	return(MG_ETYPE);
102	c_ccolor->cx = atof(av[1]);
103	c_ccolor->cy = atof(av[2]);
104	c_ccolor->flags = C_CDXY\|C_CSXY;
105	if ((c_ccolor->cx < 0.) \| (c_ccolor->cy < 0.) \|
106	(c_ccolor->cx + c_ccolor->cy > 1.))
107	return(MG_EILL);
108	c_ccolor->clock++;
109	return(MG_OK);
110	case MG_E_CSPEC: /* assign spectral values */
111	if (ac < 5)
112	return(MG_EARGC);
113	if (!isflt(av[1]) \| !isflt(av[2]))
114	return(MG_ETYPE);
115	return(setspectrum(c_ccolor, atof(av[1]), atof(av[2]),
116	ac-3, av+3));
117	case MG_E_CCT: /* assign black body spectrum */
118	if (ac != 2)
119	return(MG_EARGC);
120	if (!isflt(av[1]))
121	return(MG_ETYPE);
122	if (!c_bbtemp(c_ccolor, atof(av[1])))
123	return(MG_EILL);
124	c_ccolor->clock++;
125	return(MG_OK);
126	case MG_E_CMIX: /* mix colors */
127	if (ac < 5 \|\| (ac-1)%2)
128	return(MG_EARGC);
129	if (!isflt(av[1]))
130	return(MG_ETYPE);
131	wsum = atof(av[1]);
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 ((lp = lu_find(&clr_tab, av[i+1])) == NULL)
142	return(MG_EMEM);
143	if (lp->data == NULL)
144	return(MG_EUNDEF);
145	c_cmix(c_ccolor, wsum, c_ccolor,
146	w, (C_COLOR *)lp->data);
147	wsum += w;
148	}
149	if (wsum <= 0.)
150	return(MG_EILL);
151	c_ccolor->clock++;
152	return(MG_OK);
153	}
154	return(MG_EUNK);
155	}
156
157
158	int
159	c_hmaterial(int ac, char *av) / handle material entity */
160	{
161	int i;
162	register LUENT *lp;
163
164	switch (mg_entity(av[0])) {
165	case MG_E_MATERIAL: /* get/set material context */
166	if (ac > 4)
167	return(MG_EARGC);
168	if (ac == 1) { /* set unnamed material context */
169	c_unmaterial = c_dfmaterial;
170	c_cmaterial = &c_unmaterial;
171	c_cmname = NULL;
172	return(MG_OK);
173	}
174	if (!isname(av[1]))
175	return(MG_EILL);
176	lp = lu_find(&mat_tab, av[1]); /* lookup context */
177	if (lp == NULL)
178	return(MG_EMEM);
179	c_cmname = lp->key;
180	c_cmaterial = (C_MATERIAL *)lp->data;
181	if (ac == 2) { /* reestablish previous context */
182	if (c_cmaterial == NULL)
183	return(MG_EUNDEF);
184	return(MG_OK);
185	}
186	if (av[2][0] != '=' \|\| av[2][1])
187	return(MG_ETYPE);
188	if (c_cmaterial == NULL) { /* create new material */
189	lp->key = (char *)malloc(strlen(av[1])+1);
190	if (lp->key == NULL)
191	return(MG_EMEM);
192	strcpy(lp->key, av[1]);
193	lp->data = (char *)malloc(sizeof(C_MATERIAL));
194	if (lp->data == NULL)
195	return(MG_EMEM);
196	c_cmname = lp->key;
197	c_cmaterial = (C_MATERIAL *)lp->data;
198	c_cmaterial->clock = 0;
199	c_cmaterial->client_data = NULL;
200	}
201	i = c_cmaterial->clock;
202	if (ac == 3) { /* use default template */
203	*c_cmaterial = c_dfmaterial;
204	c_cmaterial->clock = i + 1;
205	return(MG_OK);
206	}
207	lp = lu_find(&mat_tab, av[3]); /* lookup template */
208	if (lp == NULL)
209	return(MG_EMEM);
210	if (lp->data == NULL)
211	return(MG_EUNDEF);
212	c_cmaterial = (C_MATERIAL *)lp->data;
213	c_cmaterial->clock = i + 1;
214	return(MG_OK);
215	case MG_E_IR: /* set index of refraction */
216	if (ac != 3)
217	return(MG_EARGC);
218	if (!isflt(av[1]) \| !isflt(av[2]))
219	return(MG_ETYPE);
220	c_cmaterial->nr = atof(av[1]);
221	c_cmaterial->ni = atof(av[2]);
222	if (c_cmaterial->nr <= FTINY)
223	return(MG_EILL);
224	c_cmaterial->clock++;
225	return(MG_OK);
226	case MG_E_RD: /* set diffuse reflectance */
227	if (ac != 2)
228	return(MG_EARGC);
229	if (!isflt(av[1]))
230	return(MG_ETYPE);
231	c_cmaterial->rd = atof(av[1]);
232	if ((c_cmaterial->rd < 0.) \| (c_cmaterial->rd > 1.))
233	return(MG_EILL);
234	c_cmaterial->rd_c = *c_ccolor;
235	c_cmaterial->clock++;
236	return(MG_OK);
237	case MG_E_ED: /* set diffuse emittance */
238	if (ac != 2)
239	return(MG_EARGC);
240	if (!isflt(av[1]))
241	return(MG_ETYPE);
242	c_cmaterial->ed = atof(av[1]);
243	if (c_cmaterial->ed < 0.)
244	return(MG_EILL);
245	c_cmaterial->ed_c = *c_ccolor;
246	c_cmaterial->clock++;
247	return(MG_OK);
248	case MG_E_TD: /* set diffuse transmittance */
249	if (ac != 2)
250	return(MG_EARGC);
251	if (!isflt(av[1]))
252	return(MG_ETYPE);
253	c_cmaterial->td = atof(av[1]);
254	if ((c_cmaterial->td < 0.) \| (c_cmaterial->td > 1.))
255	return(MG_EILL);
256	c_cmaterial->td_c = *c_ccolor;
257	c_cmaterial->clock++;
258	return(MG_OK);
259	case MG_E_RS: /* set specular reflectance */
260	if (ac != 3)
261	return(MG_EARGC);
262	if (!isflt(av[1]) \| !isflt(av[2]))
263	return(MG_ETYPE);
264	c_cmaterial->rs = atof(av[1]);
265	c_cmaterial->rs_a = atof(av[2]);
266	if ((c_cmaterial->rs < 0.) \| (c_cmaterial->rs > 1.) \|
267	(c_cmaterial->rs_a < 0.))
268	return(MG_EILL);
269	c_cmaterial->rs_c = *c_ccolor;
270	c_cmaterial->clock++;
271	return(MG_OK);
272	case MG_E_TS: /* set specular transmittance */
273	if (ac != 3)
274	return(MG_EARGC);
275	if (!isflt(av[1]) \| !isflt(av[2]))
276	return(MG_ETYPE);
277	c_cmaterial->ts = atof(av[1]);
278	c_cmaterial->ts_a = atof(av[2]);
279	if ((c_cmaterial->ts < 0.) \| (c_cmaterial->ts > 1.) \|
280	(c_cmaterial->ts_a < 0.))
281	return(MG_EILL);
282	c_cmaterial->ts_c = *c_ccolor;
283	c_cmaterial->clock++;
284	return(MG_OK);
285	case MG_E_SIDES: /* set number of sides */
286	if (ac != 2)
287	return(MG_EARGC);
288	if (!isint(av[1]))
289	return(MG_ETYPE);
290	i = atoi(av[1]);
291	if (i == 1)
292	c_cmaterial->sided = 1;
293	else if (i == 2)
294	c_cmaterial->sided = 0;
295	else
296	return(MG_EILL);
297	c_cmaterial->clock++;
298	return(MG_OK);
299	}
300	return(MG_EUNK);
301	}
302
303
304	int
305	c_hvertex(int ac, char *av) / handle a vertex entity */
306	{
307	int i;
308	register LUENT *lp;
309
310	switch (mg_entity(av[0])) {
311	case MG_E_VERTEX: /* get/set vertex context */
312	if (ac > 4)
313	return(MG_EARGC);
314	if (ac == 1) { /* set unnamed vertex context */
315	c_unvertex = c_dfvertex;
316	c_cvertex = &c_unvertex;
317	c_cvname = NULL;
318	return(MG_OK);
319	}
320	if (!isname(av[1]))
321	return(MG_EILL);
322	lp = lu_find(&vtx_tab, av[1]); /* lookup context */
323	if (lp == NULL)
324	return(MG_EMEM);
325	c_cvname = lp->key;
326	c_cvertex = (C_VERTEX *)lp->data;
327	if (ac == 2) { /* reestablish previous context */
328	if (c_cvertex == NULL)
329	return(MG_EUNDEF);
330	return(MG_OK);
331	}
332	if (av[2][0] != '=' \|\| av[2][1])
333	return(MG_ETYPE);
334	if (c_cvertex == NULL) { /* create new vertex context */
335	lp->key = (char *)malloc(strlen(av[1])+1);
336	if (lp->key == NULL)
337	return(MG_EMEM);
338	strcpy(lp->key, av[1]);
339	lp->data = (char *)malloc(sizeof(C_VERTEX));
340	if (lp->data == NULL)
341	return(MG_EMEM);
342	c_cvname = lp->key;
343	c_cvertex = (C_VERTEX *)lp->data;
344	c_cvertex->clock = 0;
345	c_cvertex->client_data = NULL;
346	}
347	i = c_cvertex->clock;
348	if (ac == 3) { /* use default template */
349	*c_cvertex = c_dfvertex;
350	c_cvertex->clock = i + 1;
351	return(MG_OK);
352	}
353	lp = lu_find(&vtx_tab, av[3]); /* lookup template */
354	if (lp == NULL)
355	return(MG_EMEM);
356	if (lp->data == NULL)
357	return(MG_EUNDEF);
358	c_cvertex = (C_VERTEX *)lp->data;
359	c_cvertex->clock = i + 1;
360	return(MG_OK);
361	case MG_E_POINT: /* set point */
362	if (ac != 4)
363	return(MG_EARGC);
364	if (!isflt(av[1]) \| !isflt(av[2]) \| !isflt(av[3]))
365	return(MG_ETYPE);
366	c_cvertex->p[0] = atof(av[1]);
367	c_cvertex->p[1] = atof(av[2]);
368	c_cvertex->p[2] = atof(av[3]);
369	c_cvertex->clock++;
370	return(MG_OK);
371	case MG_E_NORMAL: /* set normal */
372	if (ac != 4)
373	return(MG_EARGC);
374	if (!isflt(av[1]) \| !isflt(av[2]) \| !isflt(av[3]))
375	return(MG_ETYPE);
376	c_cvertex->n[0] = atof(av[1]);
377	c_cvertex->n[1] = atof(av[2]);
378	c_cvertex->n[2] = atof(av[3]);
379	(void)normalize(c_cvertex->n);
380	c_cvertex->clock++;
381	return(MG_OK);
382	}
383	return(MG_EUNK);
384	}
385
386
387	void
388	c_clearall(void) /* empty context tables */
389	{
390	c_uncolor = c_dfcolor;
391	c_ccolor = &c_uncolor;
392	c_ccname = NULL;
393	lu_done(&clr_tab);
394	c_unmaterial = c_dfmaterial;
395	c_cmaterial = &c_unmaterial;
396	c_cmname = NULL;
397	lu_done(&mat_tab);
398	c_unvertex = c_dfvertex;
399	c_cvertex = &c_unvertex;
400	c_cvname = NULL;
401	lu_done(&vtx_tab);
402	}
403
404
405	C_MATERIAL *
406	c_getmaterial(char name) / get a named material */
407	{
408	register LUENT *lp;
409
410	if ((lp = lu_find(&mat_tab, name)) == NULL)
411	return(NULL);
412	return((C_MATERIAL *)lp->data);
413	}
414
415
416	C_VERTEX *
417	c_getvert(char name) / get a named vertex */
418	{
419	register LUENT *lp;
420
421	if ((lp = lu_find(&vtx_tab, name)) == NULL)
422	return(NULL);
423	return((C_VERTEX *)lp->data);
424	}
425
426
427	C_COLOR *
428	c_getcolor(char name) / get a named color */
429	{
430	register LUENT *lp;
431
432	if ((lp = lu_find(&clr_tab, name)) == NULL)
433	return(NULL);
434	return((C_COLOR *)lp->data);
435	}
436
437
438	static int
439	setspectrum( /* convert a spectrum */
440	register C_COLOR *clr,
441	double wlmin,
442	double wlmax,
443	int ac,
444	char **av
445	)
446	{
447	double scale;
448	float va[C_CNSS];
449	register int i, pos;
450	int n, imax;
451	int wl;
452	double wl0, wlstep;
453	double boxpos, boxstep;
454	/* check bounds */
455	if ((wlmax <= C_CMINWL) \| (wlmax <= wlmin) \| (wlmin >= C_CMAXWL))
456	return(MG_EILL);
457	wlstep = (wlmax - wlmin)/(ac-1);
458	while (wlmin < C_CMINWL) {
459	wlmin += wlstep;
460	ac--; av++;
461	}
462	while (wlmax > C_CMAXWL) {
463	wlmax -= wlstep;
464	ac--;
465	}
466	imax = ac; /* box filter if necessary */
467	boxpos = 0;
468	boxstep = 1;
469	if (wlstep < C_CWLI) {
470	imax = (wlmax - wlmin)/C_CWLI + (1-FTINY);
471	boxpos = (wlmin - C_CMINWL)/C_CWLI;
472	boxstep = wlstep/C_CWLI;
473	wlstep = C_CWLI;
474	}
475	scale = 0.; /* get values and maximum */
476	pos = 0;
477	for (i = 0; i < imax; i++) {
478	va[i] = 0.; n = 0;
479	while (boxpos < i+.5 && pos < ac) {
480	if (!isflt(av[pos]))
481	return(MG_ETYPE);
482	va[i] += atof(av[pos++]);
483	n++;
484	boxpos += boxstep;
485	}
486	if (n > 1)
487	va[i] /= (double)n;
488	if (va[i] > scale)
489	scale = va[i];
490	else if (va[i] < -scale)
491	scale = -va[i];
492	}
493	if (scale <= FTINY)
494	return(MG_EILL);
495	scale = C_CMAXV / scale;
496	clr->ssum = 0; /* convert to our spacing */
497	wl0 = wlmin;
498	pos = 0;
499	for (i = 0, wl = C_CMINWL; i < C_CNSS; i++, wl += C_CWLI)
500	if ((wl < wlmin) \| (wl > wlmax))
501	clr->ssamp[i] = 0;
502	else {
503	while (wl0 + wlstep < wl+FTINY) {
504	wl0 += wlstep;
505	pos++;
506	}
507	if ((wl+FTINY >= wl0) & (wl-FTINY <= wl0))
508	clr->ssamp[i] = scale*va[pos] + .5;
509	else /* interpolate if necessary */
510	clr->ssamp[i] = .5 + scale / wlstep *
511	( va[pos]*(wl0+wlstep - wl) +
512	va[pos+1]*(wl - wl0) );
513	clr->ssum += clr->ssamp[i];
514	}
515	clr->flags = C_CDSPEC\|C_CSSPEC;
516	clr->clock++;
517	return(MG_OK);
518	}