src/util/rmtxop.c

#ifndef lint
static const char RCSid[] = "$Id: rmtxop.c,v 2.12 2018/08/27 23:03:05 greg Exp $";
#endif
/*
 * General component matrix operations.
 */

#include <stdio.h>
#include <stdlib.h>
#include <errno.h>
#include "rtio.h"
#include "resolu.h"
#include "rmatrix.h"
#include "platform.h"

#define MAXCOMP         16              /* #components we support */

static const char       stdin_name[] = "<stdin>";

/* unary matrix operation(s) */
typedef struct {
        double          sca[MAXCOMP];           /* scalar coefficients */
        double          cmat[MAXCOMP*MAXCOMP];  /* component transformation */
        short           nsf;                    /* number of scalars */
        short           clen;                   /* number of coefficients */
        short           transpose;              /* do transpose? */
} RUNARYOP;

/* matrix input source and requested operation(s) */
typedef struct {
        const char      *inspec;                /* input specification */
        RUNARYOP        preop;                  /* unary operation(s) */
        RMATRIX         *mtx;                   /* original matrix if loaded */
        int             binop;                  /* binary op with next (or 0) */
} ROPMAT;

int     verbose = 0;                    /* verbose reporting? */

/* Load matrix */
static int
loadmatrix(ROPMAT *rop)
{
        if (rop->mtx != NULL)
                return(0);

        rop->mtx = rmx_load(rop->inspec == stdin_name ?
                                (const char *)NULL : rop->inspec);
        if (rop->mtx == NULL) {
                fputs(rop->inspec, stderr);
                fputs(": cannot load matrix\n", stderr);
                return(-1);
        }
        return(1);
}

/* Get matrix and perform unary operations */
static RMATRIX *
loadop(ROPMAT *rop)
{
        RMATRIX *mres;
        int     i;

        if (loadmatrix(rop) < 0)                /* make sure we're loaded */
                return(NULL);

        if (rop->preop.nsf > 0) {               /* apply scalar(s) */
                if (rop->preop.clen > 0) {
                        fputs("Options -s and -c are exclusive\n", stderr);
                        goto failure;
                }
                if (rop->preop.nsf == 1) {
                        for (i = rop->mtx->ncomp; --i; )
                                rop->preop.sca[i] = rop->preop.sca[0];
                } else if (rop->preop.nsf != rop->mtx->ncomp) {
                        fprintf(stderr, "%s: -s must have one or %d factors\n",
                                        rop->inspec, rop->mtx->ncomp);
                        goto failure;
                }
                if (!rmx_scale(rop->mtx, rop->preop.sca)) {
                        fputs(rop->inspec, stderr);
                        fputs(": scalar operation failed\n", stderr);
                        goto failure;
                }
                if (verbose) {
                        fputs(rop->inspec, stderr);
                        fputs(": applied scalar (", stderr);
                        for (i = 0; i < rop->preop.nsf; i++)
                                fprintf(stderr, " %f", rop->preop.sca[i]);
                        fputs(" )\n", stderr);
                }
        }
        if (rop->preop.clen > 0) {      /* apply transform */
                if (rop->preop.clen % rop->mtx->ncomp) {
                        fprintf(stderr, "%s: -c must have N x %d coefficients\n",
                                        rop->inspec, rop->mtx->ncomp);
                        goto failure;
                }
                mres = rmx_transform(rop->mtx, rop->preop.clen/rop->mtx->ncomp,
                                        rop->preop.cmat);
                if (mres == NULL) {
                        fprintf(stderr, "%s: matrix transform failed\n",
                                                rop->inspec);
                        goto failure;
                }
                if (verbose)
                        fprintf(stderr, "%s: applied %d x %d transform\n",
                                        rop->inspec, mres->ncomp,
                                        rop->mtx->ncomp);
                rmx_free(rop->mtx);
                rop->mtx = mres;
        }
        if (rop->preop.transpose) {     /* transpose matrix? */
                mres = rmx_transpose(rop->mtx);
                if (mres == NULL) {
                        fputs(rop->inspec, stderr);
                        fputs(": transpose failed\n", stderr);
                        goto failure;
                }
                if (verbose) {
                        fputs(rop->inspec, stderr);
                        fputs(": transposed rows and columns\n", stderr);
                }
                rmx_free(rop->mtx);
                rop->mtx = mres;
        }
        mres = rop->mtx;
        rop->mtx = NULL;
        return(mres);
failure:
        rmx_free(rop->mtx);
        return(rop->mtx = NULL);
}

/* Execute binary operation, free matrix arguments and return new result */
static RMATRIX *
binaryop(const char *inspec, RMATRIX *mleft, int op, RMATRIX *mright)
{
        RMATRIX *mres = NULL;
        int     i;

        if ((mleft == NULL) | (mright == NULL))
                return(NULL);

        switch (op) {
        case '.':                       /* concatenate */
                mres = rmx_multiply(mleft, mright);
                rmx_free(mleft);
                rmx_free(mright);
                if (mres == NULL) {
                        fputs(inspec, stderr);
                        if (mleft->ncols != mright->nrows)
                                fputs(": mismatched dimensions for multiply\n",
                                                stderr);
                        else
                                fputs(": concatenation failed\n", stderr);
                        return(NULL);
                }
                if (verbose) {
                        fputs(inspec, stderr);
                        fputs(": concatenated matrix\n", stderr);
                }
                break;
        case '+':
                if (!rmx_sum(mleft, mright, NULL)) {
                        fputs(inspec, stderr);
                        fputs(": matrix sum failed\n", stderr);
                        rmx_free(mleft);
                        rmx_free(mright);
                        return(NULL);
                }
                if (verbose) {
                        fputs(inspec, stderr);
                        fputs(": added in matrix\n", stderr);
                }
                rmx_free(mright);
                mres = mleft;
                break;
        case '*':
        case '/': {
                const char *    tnam = (op == '/') ?
                                        "division" : "multiplication";
                errno = 0;
                if (!rmx_elemult(mleft, mright, (op == '/'))) {
                        fprintf(stderr, "%s: element-wise %s failed\n",
                                        inspec, tnam);
                        rmx_free(mleft);
                        rmx_free(mright);
                        return(NULL);
                }
                if (errno)
                        fprintf(stderr,
                                "%s: warning - error during element-wise %s\n",
                                        inspec, tnam);
                else if (verbose)
                        fprintf(stderr, "%s: element-wise %s\n", inspec, tnam);
                rmx_free(mright);
                mres = mleft;
                } break;
        default:
                fprintf(stderr, "%s: unknown operation '%c'\n", inspec, op);
                rmx_free(mleft);
                rmx_free(mright);
                return(NULL);
        }
        return(mres);
}

/* Perform matrix operations from left to right */
static RMATRIX *
op_left2right(ROPMAT *mop)
{
        RMATRIX *mleft = loadop(mop);

        while (mop->binop) {
                if (mleft == NULL)
                        break;
                mleft = binaryop(mop[1].inspec,
                                mleft, mop->binop, loadop(mop+1));
                mop++;
        }
        return(mleft);
}

/* Perform matrix operations from right to left */
static RMATRIX *
op_right2left(ROPMAT *mop)
{
        RMATRIX *mright;
        int     rpos = 0;
                                        /* find end of list */
        while (mop[rpos].binop)
                rpos++;
        mright = loadop(mop+rpos);
        while (rpos-- > 0) {
                if (mright == NULL)
                        break;
                mright = binaryop(mop[rpos].inspec,
                                loadop(mop+rpos), mop[rpos].binop, mright);
        }
        return(mright);
}

#define t_nrows(mop)    ((mop)->preop.transpose ? (mop)->mtx->ncols \
                                                : (mop)->mtx->nrows)
#define t_ncols(mop)    ((mop)->preop.transpose ? (mop)->mtx->nrows \
                                                : (mop)->mtx->ncols)

/* Should we prefer concatenating from rightmost matrix towards left? */
static int
prefer_right2left(ROPMAT *mop)
{
        int     mri = 0;

        while (mop[mri].binop)          /* find rightmost matrix */
                if (mop[mri++].binop != '.')
                        return(0);      /* pre-empt reversal for other ops */

        if (mri <= 1)
                return(0);              /* won't matter */

        if (loadmatrix(mop+mri) < 0)    /* load rightmost cat */
                return(1);              /* fail will bail in a moment */

        if (t_ncols(mop+mri) == 1)
                return(1);              /* definitely better R->L */

        if (t_ncols(mop+mri) >= t_nrows(mop+mri))
                return(0);              /* ...probably worse */

        if (loadmatrix(mop) < 0)        /* load leftmost */
                return(0);              /* fail will bail in a moment */

        return(t_ncols(mop+mri) < t_nrows(mop));
}

static int
get_factors(double da[], int n, char *av[])
{
        int     ac;

        for (ac = 0; ac < n && isflt(av[ac]); ac++)
                da[ac] = atof(av[ac]);
        return(ac);
}

static ROPMAT *
grow_moparray(ROPMAT *mop, int n2alloc)
{
        int     nmats = 0;

        while (mop[nmats++].binop)
                ;
        mop = (ROPMAT *)realloc(mop, n2alloc*sizeof(ROPMAT));
        if (mop == NULL) {
                fputs("Out of memory in grow_moparray()\n", stderr);
                exit(1);
        }
        if (n2alloc > nmats)
                memset(mop+nmats, 0, (n2alloc-nmats)*sizeof(ROPMAT));
        return(mop);
}

/* Load one or more matrices and operate on them, sending results to stdout */
int
main(int argc, char *argv[])
{
        int     outfmt = DTfromHeader;
        int     nall = 2;
        ROPMAT  *mop = (ROPMAT *)calloc(nall, sizeof(ROPMAT));
        int     nmats = 0;
        RMATRIX *mres = NULL;
        int     stdin_used = 0;
        int     i;
                                        /* get options and arguments */
        for (i = 1; i < argc; i++) {
                if (nmats >= nall)
                        mop = grow_moparray(mop, nall += 2);
                if (argv[i][0] && !argv[i][1] &&
                                strchr(".+*/", argv[i][0]) != NULL) {
                        if (mop[nmats].inspec == NULL || mop[nmats].binop) {
                                fprintf(stderr, "%s: missing matrix argument\n",
                                                argv[0]);
                                return(1);
                        }
                        mop[nmats++].binop = argv[i][0];
                } else if (argv[i][0] != '-' || !argv[i][1]) {
                        if (argv[i][0] == '-') {
                                if (stdin_used++) {
                                        fprintf(stderr,
                        "%s: standard input used for more than one matrix\n",
                                                argv[0]);
                                        return(1);
                                }
                                mop[nmats].inspec = stdin_name;
                        } else
                                mop[nmats].inspec = argv[i];
                        if (nmats > 0 && !mop[nmats-1].binop)
                                mop[nmats-1].binop = '.';
                        nmats++;
                } else {
                        int     n = argc-1 - i;
                        switch (argv[i][1]) {   /* get option */
                        case 'v':
                                verbose = !verbose;
                                break;
                        case 'f':
                                switch (argv[i][2]) {
                                case 'd':
                                        outfmt = DTdouble;
                                        break;
                                case 'f':
                                        outfmt = DTfloat;
                                        break;
                                case 'a':
                                        outfmt = DTascii;
                                        break;
                                case 'c':
                                        outfmt = DTrgbe;
                                        break;
                                default:
                                        goto userr;
                                }
                                break;
                        case 't':
                                mop[nmats].preop.transpose = 1;
                                break;
                        case 's':
                                if (n > MAXCOMP) n = MAXCOMP;
                                i += mop[nmats].preop.nsf =
                                        get_factors(mop[nmats].preop.sca,
                                                        n, argv+i+1);
                                break;
                        case 'c':
                                if (n > MAXCOMP*MAXCOMP) n = MAXCOMP*MAXCOMP;
                                i += mop[nmats].preop.clen =
                                        get_factors(mop[nmats].preop.cmat,
                                                        n, argv+i+1);
                                break;
                        default:
                                fprintf(stderr, "%s: unknown operation '%s'\n",
                                                argv[0], argv[i]);
                                goto userr;
                        }
                }
        }
        if (mop[0].inspec == NULL)      /* nothing to do? */
                goto userr;
                                        /* favor quicker concatenation */
        mres = prefer_right2left(mop) ? op_right2left(mop) : op_left2right(mop);
        if (!mres)
                return(1);
                                        /* write result to stdout */
        if (outfmt == DTfromHeader)
                outfmt = mres->dtype;
        if (outfmt != DTascii)
                SET_FILE_BINARY(stdout);
        newheader("RADIANCE", stdout);
        printargs(argc, argv, stdout);
        if (!rmx_write(mres, outfmt, stdout)) {
                fprintf(stderr, "%s: error writing result matrix\n", argv[0]);
                return(1);
        }
        /* rmx_free(mres); free(mop); */
        return(0);
userr:
        fprintf(stderr,
        "Usage: %s [-v][-f[adfc][-t][-s sf .. | -c ce ..] m1 [.+*/] .. > mres\n",
                        argv[0]);
        return(1);
}
Revision:	2.13
Committed:	Mon Aug 12 01:20:26 2019 UTC (4 years, 8 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.12:	+246 -107 lines
Log Message:	Take advantage of matrix multiplication associativity
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: rmtxop.c,v 2.12 2018/08/27 23:03:05 greg Exp $";
3	#endif
4	/*
5	* General component matrix operations.
6	*/
7
8	#include <stdio.h>
9	#include <stdlib.h>
10	#include <errno.h>
11	#include "rtio.h"
12	#include "resolu.h"
13	#include "rmatrix.h"
14	#include "platform.h"
15
16	#define MAXCOMP 16 /* #components we support */
17
18	static const char stdin_name[] = "<stdin>";
19
20	/* unary matrix operation(s) */
21	typedef struct {
22	double sca[MAXCOMP]; /* scalar coefficients */
23	double cmat[MAXCOMPMAXCOMP]; / component transformation */
24	short nsf; /* number of scalars */
25	short clen; /* number of coefficients */
26	short transpose; /* do transpose? */
27	} RUNARYOP;
28
29	/* matrix input source and requested operation(s) */
30	typedef struct {
31	const char inspec; / input specification */
32	RUNARYOP preop; /* unary operation(s) */
33	RMATRIX mtx; / original matrix if loaded */
34	int binop; /* binary op with next (or 0) */
35	} ROPMAT;
36
37	int verbose = 0; /* verbose reporting? */
38
39	/* Load matrix */
40	static int
41	loadmatrix(ROPMAT *rop)
42	{
43	if (rop->mtx != NULL)
44	return(0);
45
46	rop->mtx = rmx_load(rop->inspec == stdin_name ?
47	(const char *)NULL : rop->inspec);
48	if (rop->mtx == NULL) {
49	fputs(rop->inspec, stderr);
50	fputs(": cannot load matrix\n", stderr);
51	return(-1);
52	}
53	return(1);
54	}
55
56	/* Get matrix and perform unary operations */
57	static RMATRIX *
58	loadop(ROPMAT *rop)
59	{
60	RMATRIX *mres;
61	int i;
62
63	if (loadmatrix(rop) < 0) /* make sure we're loaded */
64	return(NULL);
65
66	if (rop->preop.nsf > 0) { /* apply scalar(s) */
67	if (rop->preop.clen > 0) {
68	fputs("Options -s and -c are exclusive\n", stderr);
69	goto failure;
70	}
71	if (rop->preop.nsf == 1) {
72	for (i = rop->mtx->ncomp; --i; )
73	rop->preop.sca[i] = rop->preop.sca[0];
74	} else if (rop->preop.nsf != rop->mtx->ncomp) {
75	fprintf(stderr, "%s: -s must have one or %d factors\n",
76	rop->inspec, rop->mtx->ncomp);
77	goto failure;
78	}
79	if (!rmx_scale(rop->mtx, rop->preop.sca)) {
80	fputs(rop->inspec, stderr);
81	fputs(": scalar operation failed\n", stderr);
82	goto failure;
83	}
84	if (verbose) {
85	fputs(rop->inspec, stderr);
86	fputs(": applied scalar (", stderr);
87	for (i = 0; i < rop->preop.nsf; i++)
88	fprintf(stderr, " %f", rop->preop.sca[i]);
89	fputs(" )\n", stderr);
90	}
91	}
92	if (rop->preop.clen > 0) { /* apply transform */
93	if (rop->preop.clen % rop->mtx->ncomp) {
94	fprintf(stderr, "%s: -c must have N x %d coefficients\n",
95	rop->inspec, rop->mtx->ncomp);
96	goto failure;
97	}
98	mres = rmx_transform(rop->mtx, rop->preop.clen/rop->mtx->ncomp,
99	rop->preop.cmat);
100	if (mres == NULL) {
101	fprintf(stderr, "%s: matrix transform failed\n",
102	rop->inspec);
103	goto failure;
104	}
105	if (verbose)
106	fprintf(stderr, "%s: applied %d x %d transform\n",
107	rop->inspec, mres->ncomp,
108	rop->mtx->ncomp);
109	rmx_free(rop->mtx);
110	rop->mtx = mres;
111	}
112	if (rop->preop.transpose) { /* transpose matrix? */
113	mres = rmx_transpose(rop->mtx);
114	if (mres == NULL) {
115	fputs(rop->inspec, stderr);
116	fputs(": transpose failed\n", stderr);
117	goto failure;
118	}
119	if (verbose) {
120	fputs(rop->inspec, stderr);
121	fputs(": transposed rows and columns\n", stderr);
122	}
123	rmx_free(rop->mtx);
124	rop->mtx = mres;
125	}
126	mres = rop->mtx;
127	rop->mtx = NULL;
128	return(mres);
129	failure:
130	rmx_free(rop->mtx);
131	return(rop->mtx = NULL);
132	}
133
134	/* Execute binary operation, free matrix arguments and return new result */
135	static RMATRIX *
136	binaryop(const char inspec, RMATRIX mleft, int op, RMATRIX *mright)
137	{
138	RMATRIX *mres = NULL;
139	int i;
140
141	if ((mleft == NULL) \| (mright == NULL))
142	return(NULL);
143
144	switch (op) {
145	case '.': /* concatenate */
146	mres = rmx_multiply(mleft, mright);
147	rmx_free(mleft);
148	rmx_free(mright);
149	if (mres == NULL) {
150	fputs(inspec, stderr);
151	if (mleft->ncols != mright->nrows)
152	fputs(": mismatched dimensions for multiply\n",
153	stderr);
154	else
155	fputs(": concatenation failed\n", stderr);
156	return(NULL);
157	}
158	if (verbose) {
159	fputs(inspec, stderr);
160	fputs(": concatenated matrix\n", stderr);
161	}
162	break;
163	case '+':
164	if (!rmx_sum(mleft, mright, NULL)) {
165	fputs(inspec, stderr);
166	fputs(": matrix sum failed\n", stderr);
167	rmx_free(mleft);
168	rmx_free(mright);
169	return(NULL);
170	}
171	if (verbose) {
172	fputs(inspec, stderr);
173	fputs(": added in matrix\n", stderr);
174	}
175	rmx_free(mright);
176	mres = mleft;
177	break;
178	case '*':
179	case '/': {
180	const char * tnam = (op == '/') ?
181	"division" : "multiplication";
182	errno = 0;
183	if (!rmx_elemult(mleft, mright, (op == '/'))) {
184	fprintf(stderr, "%s: element-wise %s failed\n",
185	inspec, tnam);
186	rmx_free(mleft);
187	rmx_free(mright);
188	return(NULL);
189	}
190	if (errno)
191	fprintf(stderr,
192	"%s: warning - error during element-wise %s\n",
193	inspec, tnam);
194	else if (verbose)
195	fprintf(stderr, "%s: element-wise %s\n", inspec, tnam);
196	rmx_free(mright);
197	mres = mleft;
198	} break;
199	default:
200	fprintf(stderr, "%s: unknown operation '%c'\n", inspec, op);
201	rmx_free(mleft);
202	rmx_free(mright);
203	return(NULL);
204	}
205	return(mres);
206	}
207
208	/* Perform matrix operations from left to right */
209	static RMATRIX *
210	op_left2right(ROPMAT *mop)
211	{
212	RMATRIX *mleft = loadop(mop);
213
214	while (mop->binop) {
215	if (mleft == NULL)
216	break;
217	mleft = binaryop(mop[1].inspec,
218	mleft, mop->binop, loadop(mop+1));
219	mop++;
220	}
221	return(mleft);
222	}
223
224	/* Perform matrix operations from right to left */
225	static RMATRIX *
226	op_right2left(ROPMAT *mop)
227	{
228	RMATRIX *mright;
229	int rpos = 0;
230	/* find end of list */
231	while (mop[rpos].binop)
232	rpos++;
233	mright = loadop(mop+rpos);
234	while (rpos-- > 0) {
235	if (mright == NULL)
236	break;
237	mright = binaryop(mop[rpos].inspec,
238	loadop(mop+rpos), mop[rpos].binop, mright);
239	}
240	return(mright);
241	}
242
243	#define t_nrows(mop) ((mop)->preop.transpose ? (mop)->mtx->ncols \
244	: (mop)->mtx->nrows)
245	#define t_ncols(mop) ((mop)->preop.transpose ? (mop)->mtx->nrows \
246	: (mop)->mtx->ncols)
247
248	/* Should we prefer concatenating from rightmost matrix towards left? */
249	static int
250	prefer_right2left(ROPMAT *mop)
251	{
252	int mri = 0;
253
254	while (mop[mri].binop) /* find rightmost matrix */
255	if (mop[mri++].binop != '.')
256	return(0); /* pre-empt reversal for other ops */
257
258	if (mri <= 1)
259	return(0); /* won't matter */
260
261	if (loadmatrix(mop+mri) < 0) /* load rightmost cat */
262	return(1); /* fail will bail in a moment */
263
264	if (t_ncols(mop+mri) == 1)
265	return(1); /* definitely better R->L */
266
267	if (t_ncols(mop+mri) >= t_nrows(mop+mri))
268	return(0); /* ...probably worse */
269
270	if (loadmatrix(mop) < 0) /* load leftmost */
271	return(0); /* fail will bail in a moment */
272
273	return(t_ncols(mop+mri) < t_nrows(mop));
274	}
275
276	static int
277	get_factors(double da[], int n, char *av[])
278	{
279	int ac;
280
281	for (ac = 0; ac < n && isflt(av[ac]); ac++)
282	da[ac] = atof(av[ac]);
283	return(ac);
284	}
285
286	static ROPMAT *
287	grow_moparray(ROPMAT *mop, int n2alloc)
288	{
289	int nmats = 0;
290
291	while (mop[nmats++].binop)
292	;
293	mop = (ROPMAT )realloc(mop, n2allocsizeof(ROPMAT));
294	if (mop == NULL) {
295	fputs("Out of memory in grow_moparray()\n", stderr);
296	exit(1);
297	}
298	if (n2alloc > nmats)
299	memset(mop+nmats, 0, (n2alloc-nmats)*sizeof(ROPMAT));
300	return(mop);
301	}
302
303	/* Load one or more matrices and operate on them, sending results to stdout */
304	int
305	main(int argc, char *argv[])
306	{
307	int outfmt = DTfromHeader;
308	int nall = 2;
309	ROPMAT mop = (ROPMAT )calloc(nall, sizeof(ROPMAT));
310	int nmats = 0;
311	RMATRIX *mres = NULL;
312	int stdin_used = 0;
313	int i;
314	/* get options and arguments */
315	for (i = 1; i < argc; i++) {
316	if (nmats >= nall)
317	mop = grow_moparray(mop, nall += 2);
318	if (argv[i][0] && !argv[i][1] &&
319	strchr(".+*/", argv[i][0]) != NULL) {
320	if (mop[nmats].inspec == NULL \|\| mop[nmats].binop) {
321	fprintf(stderr, "%s: missing matrix argument\n",
322	argv[0]);
323	return(1);
324	}
325	mop[nmats++].binop = argv[i][0];
326	} else if (argv[i][0] != '-' \|\| !argv[i][1]) {
327	if (argv[i][0] == '-') {
328	if (stdin_used++) {
329	fprintf(stderr,
330	"%s: standard input used for more than one matrix\n",
331	argv[0]);
332	return(1);
333	}
334	mop[nmats].inspec = stdin_name;
335	} else
336	mop[nmats].inspec = argv[i];
337	if (nmats > 0 && !mop[nmats-1].binop)
338	mop[nmats-1].binop = '.';
339	nmats++;
340	} else {
341	int n = argc-1 - i;
342	switch (argv[i][1]) { /* get option */
343	case 'v':
344	verbose = !verbose;
345	break;
346	case 'f':
347	switch (argv[i][2]) {
348	case 'd':
349	outfmt = DTdouble;
350	break;
351	case 'f':
352	outfmt = DTfloat;
353	break;
354	case 'a':
355	outfmt = DTascii;
356	break;
357	case 'c':
358	outfmt = DTrgbe;
359	break;
360	default:
361	goto userr;
362	}
363	break;
364	case 't':
365	mop[nmats].preop.transpose = 1;
366	break;
367	case 's':
368	if (n > MAXCOMP) n = MAXCOMP;
369	i += mop[nmats].preop.nsf =
370	get_factors(mop[nmats].preop.sca,
371	n, argv+i+1);
372	break;
373	case 'c':
374	if (n > MAXCOMPMAXCOMP) n = MAXCOMPMAXCOMP;
375	i += mop[nmats].preop.clen =
376	get_factors(mop[nmats].preop.cmat,
377	n, argv+i+1);
378	break;
379	default:
380	fprintf(stderr, "%s: unknown operation '%s'\n",
381	argv[0], argv[i]);
382	goto userr;
383	}
384	}
385	}
386	if (mop[0].inspec == NULL) /* nothing to do? */
387	goto userr;
388	/* favor quicker concatenation */
389	mres = prefer_right2left(mop) ? op_right2left(mop) : op_left2right(mop);
390	if (!mres)
391	return(1);
392	/* write result to stdout */
393	if (outfmt == DTfromHeader)
394	outfmt = mres->dtype;
395	if (outfmt != DTascii)
396	SET_FILE_BINARY(stdout);
397	newheader("RADIANCE", stdout);
398	printargs(argc, argv, stdout);
399	if (!rmx_write(mres, outfmt, stdout)) {
400	fprintf(stderr, "%s: error writing result matrix\n", argv[0]);
401	return(1);
402	}
403	/* rmx_free(mres); free(mop); */
404	return(0);
405	userr:
406	fprintf(stderr,
407	"Usage: %s [-v][-f[adfc][-t][-s sf .. \| -c ce ..] m1 [.+*/] .. > mres\n",
408	argv[0]);
409	return(1);
410	}