Annotation of mandoc/roff.c, Revision 1.98
1.98 ! schwarze 1: /* $Id: roff.c,v 1.97 2010/07/27 19:56:50 kristaps Exp $ */
1.1 kristaps 2: /*
1.67 kristaps 3: * Copyright (c) 2010 Kristaps Dzonsons <kristaps@bsd.lv>
1.93 schwarze 4: * Copyright (c) 2010 Ingo Schwarze <schwarze@openbsd.org>
1.1 kristaps 5: *
6: * Permission to use, copy, modify, and distribute this software for any
1.66 kristaps 7: * purpose with or without fee is hereby granted, provided that the above
8: * copyright notice and this permission notice appear in all copies.
1.1 kristaps 9: *
1.66 kristaps 10: * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
11: * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
12: * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
13: * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
14: * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
15: * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
16: * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
1.1 kristaps 17: */
1.66 kristaps 18: #ifdef HAVE_CONFIG_H
19: #include "config.h"
20: #endif
1.30 kristaps 21:
1.67 kristaps 22: #include <assert.h>
1.89 kristaps 23: #include <errno.h>
1.85 kristaps 24: #include <ctype.h>
1.89 kristaps 25: #include <limits.h>
1.1 kristaps 26: #include <stdlib.h>
1.67 kristaps 27: #include <string.h>
1.75 kristaps 28: #include <stdio.h>
1.1 kristaps 29:
1.67 kristaps 30: #include "mandoc.h"
1.43 kristaps 31: #include "roff.h"
1.94 kristaps 32: #include "libmandoc.h"
1.33 kristaps 33:
1.82 kristaps 34: #define RSTACK_MAX 128
35:
1.75 kristaps 36: #define ROFF_CTL(c) \
37: ('.' == (c) || '\'' == (c))
38:
1.88 kristaps 39: #if 1
40: #define ROFF_DEBUG(fmt, args...) \
41: do { /* Nothing. */ } while (/*CONSTCOND*/ 0)
42: #else
43: #define ROFF_DEBUG(fmt, args...) \
44: do { fprintf(stderr, fmt , ##args); } while (/*CONSTCOND*/ 0)
45: #endif
46:
1.67 kristaps 47: enum rofft {
1.80 kristaps 48: ROFF_am,
49: ROFF_ami,
50: ROFF_am1,
51: ROFF_de,
52: ROFF_dei,
53: ROFF_de1,
1.83 schwarze 54: ROFF_ds,
1.82 kristaps 55: ROFF_el,
56: ROFF_ie,
1.75 kristaps 57: ROFF_if,
1.76 kristaps 58: ROFF_ig,
1.83 schwarze 59: ROFF_rm,
60: ROFF_tr,
1.76 kristaps 61: ROFF_cblock,
1.75 kristaps 62: ROFF_ccond,
1.89 kristaps 63: ROFF_nr,
1.67 kristaps 64: ROFF_MAX
65: };
66:
1.82 kristaps 67: enum roffrule {
68: ROFFRULE_ALLOW,
69: ROFFRULE_DENY
70: };
71:
1.94 kristaps 72:
73: struct roffstr {
74: char *name; /* key of symbol */
75: char *string; /* current value */
76: struct roffstr *next; /* next in list */
77: };
78:
1.67 kristaps 79: struct roff {
80: struct roffnode *last; /* leaf of stack */
81: mandocmsg msg; /* err/warn/fatal messages */
82: void *data; /* privdata for messages */
1.82 kristaps 83: enum roffrule rstack[RSTACK_MAX]; /* stack of !`ie' rules */
84: int rstackpos; /* position in rstack */
1.90 kristaps 85: struct regset *regs; /* read/writable registers */
1.94 kristaps 86: struct roffstr *first_string;
1.79 kristaps 87: };
88:
1.67 kristaps 89: struct roffnode {
90: enum rofft tok; /* type of node */
91: struct roffnode *parent; /* up one in stack */
92: int line; /* parse line */
93: int col; /* parse col */
1.79 kristaps 94: char *end; /* end-rules: custom token */
95: int endspan; /* end-rules: next-line or infty */
1.82 kristaps 96: enum roffrule rule; /* current evaluation rule */
1.67 kristaps 97: };
98:
99: #define ROFF_ARGS struct roff *r, /* parse ctx */ \
1.72 kristaps 100: enum rofft tok, /* tok of macro */ \
1.67 kristaps 101: char **bufp, /* input buffer */ \
102: size_t *szp, /* size of input buffer */ \
103: int ln, /* parse line */ \
1.75 kristaps 104: int ppos, /* original pos in buffer */ \
105: int pos, /* current pos in buffer */ \
1.74 kristaps 106: int *offs /* reset offset of buffer data */
1.67 kristaps 107:
108: typedef enum rofferr (*roffproc)(ROFF_ARGS);
109:
110: struct roffmac {
111: const char *name; /* macro name */
1.79 kristaps 112: roffproc proc; /* process new macro */
113: roffproc text; /* process as child text of macro */
114: roffproc sub; /* process as child of macro */
115: int flags;
116: #define ROFFMAC_STRUCT (1 << 0) /* always interpret */
1.85 kristaps 117: struct roffmac *next;
1.67 kristaps 118: };
119:
1.80 kristaps 120: static enum rofferr roff_block(ROFF_ARGS);
121: static enum rofferr roff_block_text(ROFF_ARGS);
122: static enum rofferr roff_block_sub(ROFF_ARGS);
123: static enum rofferr roff_cblock(ROFF_ARGS);
124: static enum rofferr roff_ccond(ROFF_ARGS);
1.82 kristaps 125: static enum rofferr roff_cond(ROFF_ARGS);
126: static enum rofferr roff_cond_text(ROFF_ARGS);
127: static enum rofferr roff_cond_sub(ROFF_ARGS);
1.92 schwarze 128: static enum rofferr roff_ds(ROFF_ARGS);
1.94 kristaps 129: static enum roffrule roff_evalcond(const char *, int *);
130: static void roff_freestr(struct roff *);
131: static const char *roff_getstrn(const struct roff *,
132: const char *, size_t);
1.89 kristaps 133: static enum rofferr roff_line(ROFF_ARGS);
134: static enum rofferr roff_nr(ROFF_ARGS);
1.95 kristaps 135: static int roff_res(struct roff *,
136: char **, size_t *, int);
1.94 kristaps 137: static void roff_setstr(struct roff *,
138: const char *, const char *);
1.67 kristaps 139:
1.85 kristaps 140: /* See roff_hash_find() */
141:
142: #define ASCII_HI 126
143: #define ASCII_LO 33
144: #define HASHWIDTH (ASCII_HI - ASCII_LO + 1)
145:
146: static struct roffmac *hash[HASHWIDTH];
147:
148: static struct roffmac roffs[ROFF_MAX] = {
149: { "am", roff_block, roff_block_text, roff_block_sub, 0, NULL },
150: { "ami", roff_block, roff_block_text, roff_block_sub, 0, NULL },
151: { "am1", roff_block, roff_block_text, roff_block_sub, 0, NULL },
152: { "de", roff_block, roff_block_text, roff_block_sub, 0, NULL },
153: { "dei", roff_block, roff_block_text, roff_block_sub, 0, NULL },
154: { "de1", roff_block, roff_block_text, roff_block_sub, 0, NULL },
1.92 schwarze 155: { "ds", roff_ds, NULL, NULL, 0, NULL },
1.85 kristaps 156: { "el", roff_cond, roff_cond_text, roff_cond_sub, ROFFMAC_STRUCT, NULL },
157: { "ie", roff_cond, roff_cond_text, roff_cond_sub, ROFFMAC_STRUCT, NULL },
158: { "if", roff_cond, roff_cond_text, roff_cond_sub, ROFFMAC_STRUCT, NULL },
159: { "ig", roff_block, roff_block_text, roff_block_sub, 0, NULL },
160: { "rm", roff_line, NULL, NULL, 0, NULL },
161: { "tr", roff_line, NULL, NULL, 0, NULL },
162: { ".", roff_cblock, NULL, NULL, 0, NULL },
163: { "\\}", roff_ccond, NULL, NULL, 0, NULL },
1.89 kristaps 164: { "nr", roff_nr, NULL, NULL, 0, NULL },
1.67 kristaps 165: };
166:
167: static void roff_free1(struct roff *);
168: static enum rofft roff_hash_find(const char *);
1.85 kristaps 169: static void roff_hash_init(void);
1.76 kristaps 170: static void roffnode_cleanscope(struct roff *);
1.98 ! schwarze 171: static void roffnode_push(struct roff *,
1.67 kristaps 172: enum rofft, int, int);
173: static void roffnode_pop(struct roff *);
174: static enum rofft roff_parse(const char *, int *);
1.91 kristaps 175: static int roff_parse_nat(const char *, unsigned int *);
1.67 kristaps 176:
1.85 kristaps 177: /* See roff_hash_find() */
178: #define ROFF_HASH(p) (p[0] - ASCII_LO)
179:
180: static void
181: roff_hash_init(void)
182: {
183: struct roffmac *n;
184: int buc, i;
185:
186: for (i = 0; i < (int)ROFF_MAX; i++) {
187: assert(roffs[i].name[0] >= ASCII_LO);
188: assert(roffs[i].name[0] <= ASCII_HI);
189:
190: buc = ROFF_HASH(roffs[i].name);
191:
192: if (NULL != (n = hash[buc])) {
193: for ( ; n->next; n = n->next)
194: /* Do nothing. */ ;
195: n->next = &roffs[i];
196: } else
197: hash[buc] = &roffs[i];
198: }
199: }
200:
1.67 kristaps 201:
202: /*
203: * Look up a roff token by its name. Returns ROFF_MAX if no macro by
204: * the nil-terminated string name could be found.
205: */
206: static enum rofft
207: roff_hash_find(const char *p)
208: {
1.85 kristaps 209: int buc;
210: struct roffmac *n;
1.67 kristaps 211:
1.85 kristaps 212: /*
213: * libroff has an extremely simple hashtable, for the time
214: * being, which simply keys on the first character, which must
215: * be printable, then walks a chain. It works well enough until
216: * optimised.
217: */
218:
219: if (p[0] < ASCII_LO || p[0] > ASCII_HI)
220: return(ROFF_MAX);
221:
222: buc = ROFF_HASH(p);
223:
224: if (NULL == (n = hash[buc]))
225: return(ROFF_MAX);
226: for ( ; n; n = n->next)
227: if (0 == strcmp(n->name, p))
228: return((enum rofft)(n - roffs));
1.67 kristaps 229:
230: return(ROFF_MAX);
231: }
232:
233:
234: /*
235: * Pop the current node off of the stack of roff instructions currently
236: * pending.
237: */
238: static void
239: roffnode_pop(struct roff *r)
240: {
241: struct roffnode *p;
242:
1.75 kristaps 243: assert(r->last);
244: p = r->last;
1.82 kristaps 245:
246: if (ROFF_el == p->tok)
247: if (r->rstackpos > -1)
248: r->rstackpos--;
249:
1.75 kristaps 250: r->last = r->last->parent;
1.74 kristaps 251: if (p->end)
252: free(p->end);
1.67 kristaps 253: free(p);
254: }
255:
256:
257: /*
258: * Push a roff node onto the instruction stack. This must later be
259: * removed with roffnode_pop().
260: */
1.98 ! schwarze 261: static void
1.67 kristaps 262: roffnode_push(struct roff *r, enum rofft tok, int line, int col)
263: {
264: struct roffnode *p;
265:
1.98 ! schwarze 266: p = mandoc_calloc(1, sizeof(struct roffnode));
1.67 kristaps 267: p->tok = tok;
268: p->parent = r->last;
269: p->line = line;
270: p->col = col;
1.79 kristaps 271: p->rule = p->parent ? p->parent->rule : ROFFRULE_DENY;
1.67 kristaps 272:
273: r->last = p;
274: }
275:
276:
277: static void
278: roff_free1(struct roff *r)
279: {
280:
281: while (r->last)
282: roffnode_pop(r);
1.94 kristaps 283: roff_freestr(r);
1.67 kristaps 284: }
285:
286:
287: void
288: roff_reset(struct roff *r)
289: {
290:
291: roff_free1(r);
292: }
293:
294:
295: void
296: roff_free(struct roff *r)
297: {
298:
299: roff_free1(r);
300: free(r);
301: }
302:
303:
304: struct roff *
1.98 ! schwarze 305: roff_alloc(struct regset *regs, void *data, const mandocmsg msg)
1.67 kristaps 306: {
307: struct roff *r;
308:
1.98 ! schwarze 309: r = mandoc_calloc(1, sizeof(struct roff));
1.90 kristaps 310: r->regs = regs;
1.67 kristaps 311: r->msg = msg;
312: r->data = data;
1.82 kristaps 313: r->rstackpos = -1;
1.85 kristaps 314:
315: roff_hash_init();
1.67 kristaps 316: return(r);
317: }
318:
319:
1.94 kristaps 320: /*
321: * Pre-filter each and every line for reserved words (one beginning with
322: * `\*', e.g., `\*(ab'). These must be handled before the actual line
323: * is processed.
324: */
325: static int
1.95 kristaps 326: roff_res(struct roff *r, char **bufp, size_t *szp, int pos)
1.94 kristaps 327: {
328: const char *cp, *cpp, *st, *res;
329: int i, maxl;
330: size_t nsz;
331: char *n;
332:
1.95 kristaps 333: /* LINTED */
1.94 kristaps 334: for (cp = &(*bufp)[pos]; (cpp = strstr(cp, "\\*")); cp++) {
335: cp = cpp + 2;
336: switch (*cp) {
337: case ('('):
338: cp++;
339: maxl = 2;
340: break;
341: case ('['):
342: cp++;
343: maxl = 0;
344: break;
345: default:
346: maxl = 1;
347: break;
348: }
349:
350: st = cp;
351:
352: for (i = 0; 0 == maxl || i < maxl; i++, cp++) {
353: if ('\0' == *cp)
354: return(1); /* Error. */
355: if (0 == maxl && ']' == *cp)
356: break;
357: }
358:
359: res = roff_getstrn(r, st, (size_t)i);
360:
361: if (NULL == res) {
362: cp -= maxl ? 1 : 0;
363: continue;
364: }
365:
366: ROFF_DEBUG("roff: splicing reserved: [%.*s]\n", i, st);
367:
368: nsz = *szp + strlen(res) + 1;
369: n = mandoc_malloc(nsz);
370:
371: *n = '\0';
372:
373: strlcat(n, *bufp, (size_t)(cpp - *bufp + 1));
374: strlcat(n, res, nsz);
375: strlcat(n, cp + (maxl ? 0 : 1), nsz);
376:
377: free(*bufp);
378:
379: *bufp = n;
380: *szp = nsz;
381: return(0);
382: }
383:
384: return(1);
385: }
386:
387:
1.67 kristaps 388: enum rofferr
1.90 kristaps 389: roff_parseln(struct roff *r, int ln, char **bufp,
390: size_t *szp, int pos, int *offs)
1.67 kristaps 391: {
392: enum rofft t;
1.79 kristaps 393: int ppos;
394:
395: /*
1.94 kristaps 396: * Run the reserved-word filter only if we have some reserved
397: * words to fill in.
398: */
399:
1.95 kristaps 400: if (r->first_string && ! roff_res(r, bufp, szp, pos))
1.94 kristaps 401: return(ROFF_RERUN);
402:
403: /*
1.79 kristaps 404: * First, if a scope is open and we're not a macro, pass the
405: * text through the macro's filter. If a scope isn't open and
406: * we're not a macro, just let it through.
407: */
1.74 kristaps 408:
1.75 kristaps 409: if (r->last && ! ROFF_CTL((*bufp)[pos])) {
1.78 kristaps 410: t = r->last->tok;
411: assert(roffs[t].text);
1.88 kristaps 412: ROFF_DEBUG("roff: intercept scoped text: %s, [%s]\n",
413: roffs[t].name, &(*bufp)[pos]);
1.78 kristaps 414: return((*roffs[t].text)
1.90 kristaps 415: (r, t, bufp, szp,
416: ln, pos, pos, offs));
1.94 kristaps 417: } else if ( ! ROFF_CTL((*bufp)[pos]))
1.67 kristaps 418: return(ROFF_CONT);
419:
1.79 kristaps 420: /*
421: * If a scope is open, go to the child handler for that macro,
422: * as it may want to preprocess before doing anything with it.
423: */
1.78 kristaps 424:
1.79 kristaps 425: if (r->last) {
426: t = r->last->tok;
427: assert(roffs[t].sub);
1.88 kristaps 428: ROFF_DEBUG("roff: intercept scoped context: %s\n",
429: roffs[t].name);
1.79 kristaps 430: return((*roffs[t].sub)
1.90 kristaps 431: (r, t, bufp, szp,
432: ln, pos, pos, offs));
1.79 kristaps 433: }
1.78 kristaps 434:
1.79 kristaps 435: /*
436: * Lastly, as we've no scope open, try to look up and execute
437: * the new macro. If no macro is found, simply return and let
438: * the compilers handle it.
439: */
1.67 kristaps 440:
1.75 kristaps 441: ppos = pos;
1.94 kristaps 442: if (ROFF_MAX == (t = roff_parse(*bufp, &pos)))
1.79 kristaps 443: return(ROFF_CONT);
1.67 kristaps 444:
1.88 kristaps 445: ROFF_DEBUG("roff: intercept new-scope: %s, [%s]\n",
446: roffs[t].name, &(*bufp)[pos]);
1.75 kristaps 447: assert(roffs[t].proc);
1.78 kristaps 448: return((*roffs[t].proc)
1.90 kristaps 449: (r, t, bufp, szp,
450: ln, ppos, pos, offs));
1.74 kristaps 451: }
452:
453:
454: int
455: roff_endparse(struct roff *r)
456: {
457:
458: if (NULL == r->last)
459: return(1);
460: return((*r->msg)(MANDOCERR_SCOPEEXIT, r->data, r->last->line,
461: r->last->col, NULL));
1.67 kristaps 462: }
463:
464:
465: /*
466: * Parse a roff node's type from the input buffer. This must be in the
467: * form of ".foo xxx" in the usual way.
468: */
469: static enum rofft
470: roff_parse(const char *buf, int *pos)
471: {
472: int j;
473: char mac[5];
474: enum rofft t;
475:
1.75 kristaps 476: assert(ROFF_CTL(buf[*pos]));
477: (*pos)++;
1.67 kristaps 478:
479: while (buf[*pos] && (' ' == buf[*pos] || '\t' == buf[*pos]))
480: (*pos)++;
481:
482: if ('\0' == buf[*pos])
483: return(ROFF_MAX);
484:
485: for (j = 0; j < 4; j++, (*pos)++)
486: if ('\0' == (mac[j] = buf[*pos]))
487: break;
1.82 kristaps 488: else if (' ' == buf[*pos] || (j && '\\' == buf[*pos]))
1.67 kristaps 489: break;
490:
491: if (j == 4 || j < 1)
492: return(ROFF_MAX);
493:
494: mac[j] = '\0';
495:
496: if (ROFF_MAX == (t = roff_hash_find(mac)))
497: return(t);
498:
499: while (buf[*pos] && ' ' == buf[*pos])
500: (*pos)++;
501:
502: return(t);
503: }
504:
505:
1.89 kristaps 506: static int
1.91 kristaps 507: roff_parse_nat(const char *buf, unsigned int *res)
1.89 kristaps 508: {
509: char *ep;
510: long lval;
511:
512: errno = 0;
513: lval = strtol(buf, &ep, 10);
514: if (buf[0] == '\0' || *ep != '\0')
515: return(0);
516: if ((errno == ERANGE &&
517: (lval == LONG_MAX || lval == LONG_MIN)) ||
1.91 kristaps 518: (lval > INT_MAX || lval < 0))
1.89 kristaps 519: return(0);
520:
1.91 kristaps 521: *res = (unsigned int)lval;
1.89 kristaps 522: return(1);
523: }
524:
525:
1.67 kristaps 526: /* ARGSUSED */
527: static enum rofferr
1.76 kristaps 528: roff_cblock(ROFF_ARGS)
1.67 kristaps 529: {
530:
1.79 kristaps 531: /*
532: * A block-close `..' should only be invoked as a child of an
533: * ignore macro, otherwise raise a warning and just ignore it.
534: */
535:
1.76 kristaps 536: if (NULL == r->last) {
537: if ( ! (*r->msg)(MANDOCERR_NOSCOPE, r->data, ln, ppos, NULL))
538: return(ROFF_ERR);
539: return(ROFF_IGN);
540: }
1.67 kristaps 541:
1.81 kristaps 542: switch (r->last->tok) {
543: case (ROFF_am):
544: /* FALLTHROUGH */
545: case (ROFF_ami):
546: /* FALLTHROUGH */
547: case (ROFF_am1):
548: /* FALLTHROUGH */
549: case (ROFF_de):
550: /* FALLTHROUGH */
551: case (ROFF_dei):
552: /* FALLTHROUGH */
553: case (ROFF_de1):
554: /* FALLTHROUGH */
555: case (ROFF_ig):
556: break;
557: default:
1.76 kristaps 558: if ( ! (*r->msg)(MANDOCERR_NOSCOPE, r->data, ln, ppos, NULL))
559: return(ROFF_ERR);
1.67 kristaps 560: return(ROFF_IGN);
1.76 kristaps 561: }
1.67 kristaps 562:
1.76 kristaps 563: if ((*bufp)[pos])
564: if ( ! (*r->msg)(MANDOCERR_ARGSLOST, r->data, ln, pos, NULL))
565: return(ROFF_ERR);
1.71 kristaps 566:
567: roffnode_pop(r);
1.76 kristaps 568: roffnode_cleanscope(r);
569: return(ROFF_IGN);
1.71 kristaps 570:
1.67 kristaps 571: }
572:
573:
1.76 kristaps 574: static void
575: roffnode_cleanscope(struct roff *r)
1.67 kristaps 576: {
577:
1.76 kristaps 578: while (r->last) {
579: if (--r->last->endspan < 0)
580: break;
581: roffnode_pop(r);
582: }
1.67 kristaps 583: }
584:
585:
1.75 kristaps 586: /* ARGSUSED */
1.74 kristaps 587: static enum rofferr
1.75 kristaps 588: roff_ccond(ROFF_ARGS)
1.74 kristaps 589: {
590:
1.76 kristaps 591: if (NULL == r->last) {
592: if ( ! (*r->msg)(MANDOCERR_NOSCOPE, r->data, ln, ppos, NULL))
593: return(ROFF_ERR);
594: return(ROFF_IGN);
595: }
596:
1.82 kristaps 597: switch (r->last->tok) {
598: case (ROFF_el):
599: /* FALLTHROUGH */
600: case (ROFF_ie):
601: /* FALLTHROUGH */
602: case (ROFF_if):
603: break;
604: default:
1.75 kristaps 605: if ( ! (*r->msg)(MANDOCERR_NOSCOPE, r->data, ln, ppos, NULL))
606: return(ROFF_ERR);
607: return(ROFF_IGN);
608: }
609:
1.76 kristaps 610: if (r->last->endspan > -1) {
611: if ( ! (*r->msg)(MANDOCERR_NOSCOPE, r->data, ln, ppos, NULL))
612: return(ROFF_ERR);
613: return(ROFF_IGN);
614: }
615:
616: if ((*bufp)[pos])
617: if ( ! (*r->msg)(MANDOCERR_ARGSLOST, r->data, ln, pos, NULL))
618: return(ROFF_ERR);
619:
1.75 kristaps 620: roffnode_pop(r);
1.76 kristaps 621: roffnode_cleanscope(r);
622: return(ROFF_IGN);
623: }
624:
1.75 kristaps 625:
1.76 kristaps 626: /* ARGSUSED */
627: static enum rofferr
1.80 kristaps 628: roff_block(ROFF_ARGS)
1.76 kristaps 629: {
1.78 kristaps 630: int sv;
631: size_t sz;
1.76 kristaps 632:
1.80 kristaps 633: if (ROFF_ig != tok && '\0' == (*bufp)[pos]) {
634: if ( ! (*r->msg)(MANDOCERR_NOARGS, r->data, ln, ppos, NULL))
635: return(ROFF_ERR);
636: return(ROFF_IGN);
637: } else if (ROFF_ig != tok) {
638: while ((*bufp)[pos] && ' ' != (*bufp)[pos])
639: pos++;
640: while (' ' == (*bufp)[pos])
641: pos++;
642: }
643:
1.98 ! schwarze 644: roffnode_push(r, tok, ln, ppos);
1.76 kristaps 645:
1.79 kristaps 646: if ('\0' == (*bufp)[pos])
1.78 kristaps 647: return(ROFF_IGN);
648:
649: sv = pos;
650: while ((*bufp)[pos] && ' ' != (*bufp)[pos] &&
651: '\t' != (*bufp)[pos])
652: pos++;
653:
654: /*
655: * Note: groff does NOT like escape characters in the input.
656: * Instead of detecting this, we're just going to let it fly and
657: * to hell with it.
658: */
659:
660: assert(pos > sv);
661: sz = (size_t)(pos - sv);
662:
1.79 kristaps 663: if (1 == sz && '.' == (*bufp)[sv])
664: return(ROFF_IGN);
665:
1.98 ! schwarze 666: r->last->end = mandoc_malloc(sz + 1);
1.78 kristaps 667:
668: memcpy(r->last->end, *bufp + sv, sz);
669: r->last->end[(int)sz] = '\0';
670:
1.77 kristaps 671: if ((*bufp)[pos])
672: if ( ! (*r->msg)(MANDOCERR_ARGSLOST, r->data, ln, pos, NULL))
673: return(ROFF_ERR);
1.74 kristaps 674:
1.78 kristaps 675: return(ROFF_IGN);
676: }
677:
678:
679: /* ARGSUSED */
680: static enum rofferr
1.80 kristaps 681: roff_block_sub(ROFF_ARGS)
1.79 kristaps 682: {
683: enum rofft t;
684: int i, j;
685:
686: /*
687: * First check whether a custom macro exists at this level. If
688: * it does, then check against it. This is some of groff's
689: * stranger behaviours. If we encountered a custom end-scope
690: * tag and that tag also happens to be a "real" macro, then we
691: * need to try interpreting it again as a real macro. If it's
692: * not, then return ignore. Else continue.
693: */
694:
695: if (r->last->end) {
696: i = pos + 1;
697: while (' ' == (*bufp)[i] || '\t' == (*bufp)[i])
698: i++;
699:
700: for (j = 0; r->last->end[j]; j++, i++)
701: if ((*bufp)[i] != r->last->end[j])
702: break;
703:
704: if ('\0' == r->last->end[j] &&
705: ('\0' == (*bufp)[i] ||
706: ' ' == (*bufp)[i] ||
707: '\t' == (*bufp)[i])) {
708: roffnode_pop(r);
709: roffnode_cleanscope(r);
710:
711: if (ROFF_MAX != roff_parse(*bufp, &pos))
712: return(ROFF_RERUN);
713: return(ROFF_IGN);
714: }
715: }
716:
717: /*
718: * If we have no custom end-query or lookup failed, then try
719: * pulling it out of the hashtable.
720: */
721:
722: ppos = pos;
723: t = roff_parse(*bufp, &pos);
724:
725: /* If we're not a comment-end, then throw it away. */
726: if (ROFF_cblock != t)
727: return(ROFF_IGN);
728:
729: assert(roffs[t].proc);
1.90 kristaps 730: return((*roffs[t].proc)(r, t, bufp, szp,
731: ln, ppos, pos, offs));
1.79 kristaps 732: }
733:
734:
735: /* ARGSUSED */
736: static enum rofferr
1.80 kristaps 737: roff_block_text(ROFF_ARGS)
1.78 kristaps 738: {
739:
740: return(ROFF_IGN);
741: }
742:
743:
744: /* ARGSUSED */
745: static enum rofferr
1.82 kristaps 746: roff_cond_sub(ROFF_ARGS)
747: {
748: enum rofft t;
749: enum roffrule rr;
1.87 kristaps 750: struct roffnode *l;
1.82 kristaps 751:
752: ppos = pos;
753: rr = r->last->rule;
754:
1.87 kristaps 755: /*
756: * Clean out scope. If we've closed ourselves, then don't
757: * continue.
758: */
759:
760: l = r->last;
761: roffnode_cleanscope(r);
762:
763: if (l != r->last)
764: return(ROFFRULE_DENY == rr ? ROFF_IGN : ROFF_CONT);
1.82 kristaps 765:
766: if (ROFF_MAX == (t = roff_parse(*bufp, &pos)))
767: return(ROFFRULE_DENY == rr ? ROFF_IGN : ROFF_CONT);
768:
769: /*
770: * A denied conditional must evaluate its children if and only
771: * if they're either structurally required (such as loops and
772: * conditionals) or a closing macro.
773: */
774: if (ROFFRULE_DENY == rr)
775: if ( ! (ROFFMAC_STRUCT & roffs[t].flags))
776: if (ROFF_ccond != t)
777: return(ROFF_IGN);
778:
779: assert(roffs[t].proc);
1.90 kristaps 780: return((*roffs[t].proc)(r, t, bufp, szp,
781: ln, ppos, pos, offs));
1.82 kristaps 782: }
783:
784:
785: /* ARGSUSED */
786: static enum rofferr
787: roff_cond_text(ROFF_ARGS)
1.78 kristaps 788: {
789: char *ep, *st;
1.82 kristaps 790: enum roffrule rr;
791:
792: rr = r->last->rule;
793:
794: /*
795: * We display the value of the text if out current evaluation
796: * scope permits us to do so.
797: */
1.78 kristaps 798:
799: st = &(*bufp)[pos];
800: if (NULL == (ep = strstr(st, "\\}"))) {
801: roffnode_cleanscope(r);
1.82 kristaps 802: return(ROFFRULE_DENY == rr ? ROFF_IGN : ROFF_CONT);
1.78 kristaps 803: }
804:
1.86 kristaps 805: if (ep == st || (ep > st && '\\' != *(ep - 1)))
1.78 kristaps 806: roffnode_pop(r);
807:
808: roffnode_cleanscope(r);
1.82 kristaps 809: return(ROFFRULE_DENY == rr ? ROFF_IGN : ROFF_CONT);
1.74 kristaps 810: }
811:
812:
1.88 kristaps 813: static enum roffrule
814: roff_evalcond(const char *v, int *pos)
815: {
816:
817: switch (v[*pos]) {
818: case ('n'):
819: (*pos)++;
820: return(ROFFRULE_ALLOW);
821: case ('e'):
822: /* FALLTHROUGH */
823: case ('o'):
824: /* FALLTHROUGH */
825: case ('t'):
826: (*pos)++;
827: return(ROFFRULE_DENY);
828: default:
829: break;
830: }
831:
832: while (v[*pos] && ' ' != v[*pos])
833: (*pos)++;
834: return(ROFFRULE_DENY);
835: }
836:
837:
1.75 kristaps 838: /* ARGSUSED */
1.74 kristaps 839: static enum rofferr
1.89 kristaps 840: roff_line(ROFF_ARGS)
841: {
842:
843: return(ROFF_IGN);
844: }
845:
846:
847: /* ARGSUSED */
848: static enum rofferr
1.82 kristaps 849: roff_cond(ROFF_ARGS)
1.74 kristaps 850: {
1.77 kristaps 851: int sv;
1.88 kristaps 852: enum roffrule rule;
1.74 kristaps 853:
1.82 kristaps 854: /* Stack overflow! */
855:
856: if (ROFF_ie == tok && r->rstackpos == RSTACK_MAX - 1) {
857: (*r->msg)(MANDOCERR_MEM, r->data, ln, ppos, NULL);
858: return(ROFF_ERR);
859: }
1.74 kristaps 860:
1.88 kristaps 861: /* First, evaluate the conditional. */
1.84 schwarze 862:
1.88 kristaps 863: if (ROFF_el == tok) {
864: /*
865: * An `.el' will get the value of the current rstack
866: * entry set in prior `ie' calls or defaults to DENY.
867: */
868: if (r->rstackpos < 0)
869: rule = ROFFRULE_DENY;
870: else
871: rule = r->rstack[r->rstackpos];
872: } else
873: rule = roff_evalcond(*bufp, &pos);
1.77 kristaps 874:
875: sv = pos;
1.88 kristaps 876:
1.75 kristaps 877: while (' ' == (*bufp)[pos])
878: pos++;
1.74 kristaps 879:
1.77 kristaps 880: /*
881: * Roff is weird. If we have just white-space after the
882: * conditional, it's considered the BODY and we exit without
883: * really doing anything. Warn about this. It's probably
884: * wrong.
885: */
1.88 kristaps 886:
1.77 kristaps 887: if ('\0' == (*bufp)[pos] && sv != pos) {
1.88 kristaps 888: if ((*r->msg)(MANDOCERR_NOARGS, r->data, ln, ppos, NULL))
889: return(ROFF_IGN);
890: return(ROFF_ERR);
1.77 kristaps 891: }
892:
1.98 ! schwarze 893: roffnode_push(r, tok, ln, ppos);
1.77 kristaps 894:
1.88 kristaps 895: r->last->rule = rule;
896:
897: ROFF_DEBUG("roff: cond: %s -> %s\n", roffs[tok].name,
898: ROFFRULE_ALLOW == rule ? "allow" : "deny");
1.82 kristaps 899:
1.84 schwarze 900: if (ROFF_ie == tok) {
1.82 kristaps 901: /*
902: * An if-else will put the NEGATION of the current
903: * evaluated conditional into the stack.
904: */
905: r->rstackpos++;
906: if (ROFFRULE_DENY == r->last->rule)
907: r->rstack[r->rstackpos] = ROFFRULE_ALLOW;
908: else
909: r->rstack[r->rstackpos] = ROFFRULE_DENY;
910: }
1.88 kristaps 911:
912: /* If the parent has false as its rule, then so do we. */
913:
914: if (r->last->parent && ROFFRULE_DENY == r->last->parent->rule) {
1.84 schwarze 915: r->last->rule = ROFFRULE_DENY;
1.88 kristaps 916: ROFF_DEBUG("roff: cond override: %s -> deny\n",
917: roffs[tok].name);
918: }
919:
920: /*
921: * Determine scope. If we're invoked with "\{" trailing the
922: * conditional, then we're in a multiline scope. Else our scope
923: * expires on the next line.
924: */
1.74 kristaps 925:
1.75 kristaps 926: r->last->endspan = 1;
927:
928: if ('\\' == (*bufp)[pos] && '{' == (*bufp)[pos + 1]) {
929: r->last->endspan = -1;
930: pos += 2;
1.88 kristaps 931: ROFF_DEBUG("roff: cond-scope: %s, multi-line\n",
932: roffs[tok].name);
933: } else
934: ROFF_DEBUG("roff: cond-scope: %s, one-line\n",
935: roffs[tok].name);
1.74 kristaps 936:
1.77 kristaps 937: /*
938: * If there are no arguments on the line, the next-line scope is
939: * assumed.
940: */
941:
1.75 kristaps 942: if ('\0' == (*bufp)[pos])
943: return(ROFF_IGN);
1.77 kristaps 944:
945: /* Otherwise re-run the roff parser after recalculating. */
1.74 kristaps 946:
1.75 kristaps 947: *offs = pos;
948: return(ROFF_RERUN);
1.83 schwarze 949: }
950:
951:
952: /* ARGSUSED */
953: static enum rofferr
1.92 schwarze 954: roff_ds(ROFF_ARGS)
955: {
1.96 kristaps 956: char *name, *string;
957:
958: /*
959: * A symbol is named by the first word following the macro
960: * invocation up to a space. Its value is anything after the
961: * name's trailing whitespace and optional double-quote. Thus,
962: *
963: * [.ds foo "bar " ]
964: *
965: * will have `bar " ' as its value.
966: */
1.92 schwarze 967:
968: name = *bufp + pos;
969: if ('\0' == *name)
970: return(ROFF_IGN);
971:
972: string = name;
1.96 kristaps 973: /* Read until end of name. */
1.92 schwarze 974: while (*string && ' ' != *string)
975: string++;
1.96 kristaps 976:
977: /* Nil-terminate name. */
1.92 schwarze 978: if (*string)
1.96 kristaps 979: *(string++) = '\0';
980:
981: /* Read past spaces. */
982: while (*string && ' ' == *string)
983: string++;
984:
985: /* Read passed initial double-quote. */
1.92 schwarze 986: if (*string && '"' == *string)
987: string++;
988:
1.96 kristaps 989: /* The rest is the value. */
1.94 kristaps 990: roff_setstr(r, name, string);
1.92 schwarze 991: return(ROFF_IGN);
992: }
993:
994:
995: /* ARGSUSED */
996: static enum rofferr
1.89 kristaps 997: roff_nr(ROFF_ARGS)
1.83 schwarze 998: {
1.89 kristaps 999: const char *key, *val;
1.91 kristaps 1000: struct reg *rg;
1.89 kristaps 1001:
1002: key = &(*bufp)[pos];
1.91 kristaps 1003: rg = r->regs->regs;
1.89 kristaps 1004:
1005: /* Parse register request. */
1006: while ((*bufp)[pos] && ' ' != (*bufp)[pos])
1007: pos++;
1008:
1009: /*
1010: * Set our nil terminator. Because this line is going to be
1011: * ignored anyway, we can munge it as we please.
1012: */
1013: if ((*bufp)[pos])
1014: (*bufp)[pos++] = '\0';
1015:
1016: /* Skip whitespace to register token. */
1017: while ((*bufp)[pos] && ' ' == (*bufp)[pos])
1018: pos++;
1019:
1020: val = &(*bufp)[pos];
1021:
1022: /* Process register token. */
1023:
1024: if (0 == strcmp(key, "nS")) {
1.91 kristaps 1025: rg[(int)REG_nS].set = 1;
1026: if ( ! roff_parse_nat(val, &rg[(int)REG_nS].v.u))
1027: rg[(int)REG_nS].v.u = 0;
1.89 kristaps 1028:
1.91 kristaps 1029: ROFF_DEBUG("roff: register nS: %u\n",
1030: rg[(int)REG_nS].v.u);
1.89 kristaps 1031: } else
1032: ROFF_DEBUG("roff: ignoring register: %s\n", key);
1.83 schwarze 1033:
1034: return(ROFF_IGN);
1.92 schwarze 1035: }
1036:
1037:
1.94 kristaps 1038: static void
1039: roff_setstr(struct roff *r, const char *name, const char *string)
1.92 schwarze 1040: {
1041: struct roffstr *n;
1042: char *namecopy;
1043:
1.94 kristaps 1044: n = r->first_string;
1.92 schwarze 1045: while (n && strcmp(name, n->name))
1046: n = n->next;
1.94 kristaps 1047:
1048: if (NULL == n) {
1049: namecopy = mandoc_strdup(name);
1050: n = mandoc_malloc(sizeof(struct roffstr));
1051: n->name = namecopy;
1052: n->next = r->first_string;
1053: r->first_string = n;
1054: } else
1.92 schwarze 1055: free(n->string);
1.94 kristaps 1056:
1.96 kristaps 1057: ROFF_DEBUG("roff: new symbol: [%s] = [%s]\n", name, string);
1.94 kristaps 1058: n->string = string ? strdup(string) : NULL;
1.92 schwarze 1059: }
1060:
1061:
1.94 kristaps 1062: static const char *
1063: roff_getstrn(const struct roff *r, const char *name, size_t len)
1.92 schwarze 1064: {
1.94 kristaps 1065: const struct roffstr *n;
1.92 schwarze 1066:
1.94 kristaps 1067: n = r->first_string;
1.97 kristaps 1068: while (n && (strncmp(name, n->name, len) || '\0' != n->name[(int)len]))
1.92 schwarze 1069: n = n->next;
1.94 kristaps 1070:
1071: return(n ? n->string : NULL);
1.92 schwarze 1072: }
1073:
1.94 kristaps 1074:
1075: static void
1076: roff_freestr(struct roff *r)
1.92 schwarze 1077: {
1078: struct roffstr *n, *nn;
1079:
1.94 kristaps 1080: for (n = r->first_string; n; n = nn) {
1.92 schwarze 1081: free(n->name);
1082: free(n->string);
1083: nn = n->next;
1084: free(n);
1085: }
1.94 kristaps 1086:
1087: r->first_string = NULL;
1.74 kristaps 1088: }
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