Annotation of mandoc/mdocterm.c, Revision 1.32
1.32 ! kristaps 1: /* $Id: mdocterm.c,v 1.31 2009/03/04 14:13:05 kristaps Exp $ */
1.1 kristaps 2: /*
3: * Copyright (c) 2008 Kristaps Dzonsons <kristaps@kth.se>
4: *
5: * Permission to use, copy, modify, and distribute this software for any
6: * purpose with or without fee is hereby granted, provided that the
7: * above copyright notice and this permission notice appear in all
8: * copies.
9: *
10: * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL
11: * WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED
12: * WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE
13: * AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL
14: * DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR
15: * PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER
16: * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR
17: * PERFORMANCE OF THIS SOFTWARE.
18: */
1.18 kristaps 19: #include <sys/utsname.h>
20:
1.1 kristaps 21: #include <assert.h>
1.3 kristaps 22: #include <ctype.h>
1.1 kristaps 23: #include <err.h>
24: #include <getopt.h>
1.3 kristaps 25: #include <stdio.h>
1.1 kristaps 26: #include <stdlib.h>
1.3 kristaps 27: #include <string.h>
1.7 kristaps 28: #ifndef __OpenBSD__
1.5 kristaps 29: #include <time.h>
30: #endif
31:
1.2 kristaps 32: #include "mmain.h"
1.1 kristaps 33: #include "term.h"
34:
1.27 kristaps 35: struct termenc {
36: const char *enc;
37: int sym;
38: };
39:
1.3 kristaps 40: static void body(struct termp *,
1.12 kristaps 41: struct termpair *,
1.3 kristaps 42: const struct mdoc_meta *,
43: const struct mdoc_node *);
44: static void header(struct termp *,
45: const struct mdoc_meta *);
46: static void footer(struct termp *,
47: const struct mdoc_meta *);
48:
49: static void pword(struct termp *, const char *, size_t);
1.25 kristaps 50: static void pescape(struct termp *, const char *,
51: size_t *, size_t);
52: static void nescape(struct termp *,
1.12 kristaps 53: const char *, size_t);
1.3 kristaps 54: static void chara(struct termp *, char);
1.25 kristaps 55: static void stringa(struct termp *,
56: const char *, size_t);
57: static void symbola(struct termp *, enum tsym);
1.26 kristaps 58: static void stylea(struct termp *, enum tstyle);
1.3 kristaps 59:
60: #ifdef __linux__
61: extern size_t strlcat(char *, const char *, size_t);
62: extern size_t strlcpy(char *, const char *, size_t);
63: #endif
64:
1.27 kristaps 65: static struct termenc termenc1[] = {
66: { "\\", TERMSYM_SLASH },
67: { "\'", TERMSYM_RSQUOTE },
68: { "`", TERMSYM_LSQUOTE },
69: { "-", TERMSYM_HYPHEN },
70: { " ", TERMSYM_SPACE },
71: { ".", TERMSYM_PERIOD },
72: { "&", TERMSYM_BREAK },
73: { "e", TERMSYM_SLASH },
74: { "q", TERMSYM_DQUOTE },
75: { NULL, 0 }
76: };
77:
78: static struct termenc termenc2[] = {
79: { "rB", TERMSYM_RBRACK },
80: { "lB", TERMSYM_LBRACK },
1.31 kristaps 81: { "ra", TERMSYM_RANGLE },
82: { "la", TERMSYM_LANGLE },
1.27 kristaps 83: { "Lq", TERMSYM_LDQUOTE },
84: { "lq", TERMSYM_LDQUOTE },
85: { "Rq", TERMSYM_RDQUOTE },
86: { "rq", TERMSYM_RDQUOTE },
87: { "oq", TERMSYM_LSQUOTE },
88: { "aq", TERMSYM_RSQUOTE },
89:
90: { "<-", TERMSYM_LARROW },
91: { "->", TERMSYM_RARROW },
92: { "ua", TERMSYM_UARROW },
93: { "da", TERMSYM_DARROW },
94:
95: { "bu", TERMSYM_BULLET },
96: { "Ba", TERMSYM_BAR },
97: { "ba", TERMSYM_BAR },
98: { "co", TERMSYM_COPY },
99: { "Am", TERMSYM_AMP },
100:
101: { "Le", TERMSYM_LE },
102: { "<=", TERMSYM_LE },
103: { "Ge", TERMSYM_GE },
1.31 kristaps 104: { ">=", TERMSYM_GE },
1.27 kristaps 105: { "==", TERMSYM_EQ },
106: { "Ne", TERMSYM_NEQ },
107: { "!=", TERMSYM_NEQ },
108: { "Pm", TERMSYM_PLUSMINUS },
109: { "+-", TERMSYM_PLUSMINUS },
110: { "If", TERMSYM_INF2 },
111: { "if", TERMSYM_INF },
112: { "Na", TERMSYM_NAN },
113: { "na", TERMSYM_NAN },
114: { "**", TERMSYM_ASTERISK },
115: { "Gt", TERMSYM_GT },
116: { "Lt", TERMSYM_LT },
117:
118: { "aa", TERMSYM_ACUTE },
119: { "ga", TERMSYM_GRAVE },
120:
121: { "en", TERMSYM_EN },
122: { "em", TERMSYM_EM },
123:
124: { "Pi", TERMSYM_PI },
125: { NULL, 0 }
126: };
127:
1.25 kristaps 128: static struct termsym termsym_ansi[] = {
129: { "]", 1 }, /* TERMSYM_RBRACK */
130: { "[", 1 }, /* TERMSYM_LBRACK */
131: { "<-", 2 }, /* TERMSYM_LARROW */
132: { "->", 2 }, /* TERMSYM_RARROW */
133: { "^", 1 }, /* TERMSYM_UARROW */
134: { "v", 1 }, /* TERMSYM_DARROW */
135: { "`", 1 }, /* TERMSYM_LSQUOTE */
136: { "\'", 1 }, /* TERMSYM_RSQUOTE */
137: { "\'", 1 }, /* TERMSYM_SQUOTE */
138: { "``", 2 }, /* TERMSYM_LDQUOTE */
139: { "\'\'", 2 }, /* TERMSYM_RDQUOTE */
140: { "\"", 1 }, /* TERMSYM_DQUOTE */
141: { "<", 1 }, /* TERMSYM_LT */
142: { ">", 1 }, /* TERMSYM_GT */
143: { "<=", 2 }, /* TERMSYM_LE */
144: { ">=", 2 }, /* TERMSYM_GE */
145: { "==", 2 }, /* TERMSYM_EQ */
146: { "!=", 2 }, /* TERMSYM_NEQ */
147: { "\'", 1 }, /* TERMSYM_ACUTE */
148: { "`", 1 }, /* TERMSYM_GRAVE */
149: { "pi", 2 }, /* TERMSYM_PI */
150: { "+=", 2 }, /* TERMSYM_PLUSMINUS */
151: { "oo", 2 }, /* TERMSYM_INF */
152: { "infinity", 8 }, /* TERMSYM_INF2 */
153: { "NaN", 3 }, /* TERMSYM_NAN */
154: { "|", 1 }, /* TERMSYM_BAR */
155: { "o", 1 }, /* TERMSYM_BULLET */
1.27 kristaps 156: { "&", 1 }, /* TERMSYM_AMP */
157: { "--", 2 }, /* TERMSYM_EM */
158: { "-", 1 }, /* TERMSYM_EN */
159: { "(C)", 3 }, /* TERMSYM_COPY */
160: { "*", 1 }, /* TERMSYM_ASTERISK */
161: { "\\", 1 }, /* TERMSYM_SLASH */
162: { "-", 1 }, /* TERMSYM_HYPHEN */
163: { " ", 1 }, /* TERMSYM_SPACE */
164: { ".", 1 }, /* TERMSYM_PERIOD */
165: { "", 0 }, /* TERMSYM_BREAK */
1.31 kristaps 166: { "<", 1 }, /* TERMSYM_LANGLE */
167: { ">", 1 }, /* TERMSYM_RANGLE */
1.25 kristaps 168: };
169:
170: static const char ansi_clear[] = { 27, '[', '0', 'm' };
171: static const char ansi_bold[] = { 27, '[', '1', 'm' };
172: static const char ansi_under[] = { 27, '[', '4', 'm' };
173:
174: static struct termsym termstyle_ansi[] = {
175: { ansi_clear, 4 },
176: { ansi_bold, 4 },
177: { ansi_under, 4 }
178: };
179:
1.3 kristaps 180:
1.1 kristaps 181: int
182: main(int argc, char *argv[])
183: {
1.2 kristaps 184: struct mmain *p;
185: const struct mdoc *mdoc;
1.3 kristaps 186: struct termp termp;
1.2 kristaps 187:
188: p = mmain_alloc();
1.1 kristaps 189:
1.3 kristaps 190: if ( ! mmain_getopt(p, argc, argv, NULL, NULL, NULL, NULL))
1.2 kristaps 191: mmain_exit(p, 1);
1.1 kristaps 192:
1.3 kristaps 193: if (NULL == (mdoc = mmain_mdoc(p)))
194: mmain_exit(p, 1);
195:
1.29 kristaps 196: termp.maxrmargin = termp.rmargin = 78; /* XXX */
1.3 kristaps 197: termp.maxcols = 1024;
198: termp.offset = termp.col = 0;
199: termp.flags = TERMP_NOSPACE;
1.25 kristaps 200: termp.symtab = termsym_ansi;
201: termp.styletab = termstyle_ansi;
1.3 kristaps 202:
203: if (NULL == (termp.buf = malloc(termp.maxcols)))
204: err(1, "malloc");
205:
1.15 kristaps 206: header(&termp, mdoc_meta(mdoc));
1.12 kristaps 207: body(&termp, NULL, mdoc_meta(mdoc), mdoc_node(mdoc));
1.3 kristaps 208: footer(&termp, mdoc_meta(mdoc));
209:
210: free(termp.buf);
211:
212: mmain_exit(p, 0);
213: /* NOTREACHED */
214: }
215:
216:
1.25 kristaps 217: /*
218: * Flush a line of text. A "line" is loosely defined as being something
219: * that should be followed by a newline, regardless of whether it's
220: * broken apart by newlines getting there. A line can also be a
221: * fragment of a columnar list.
222: *
223: * Specifically, a line is whatever's in p->buf of length p->col, which
224: * is zeroed after this function returns.
225: *
226: * The variables TERMP_NOLPAD, TERMP_LITERAL and TERMP_NOBREAK are of
227: * critical importance here. Their behaviour follows:
228: *
229: * - TERMP_NOLPAD: when beginning to write the line, don't left-pad the
230: * offset value. This is useful when doing columnar lists where the
231: * prior column has right-padded.
232: *
233: * - TERMP_NOBREAK: this is the most important and is used when making
234: * columns. In short: don't print a newline and instead pad to the
235: * right margin. Used in conjunction with TERMP_NOLPAD.
236: *
237: * In-line line breaking:
238: *
239: * If TERMP_NOBREAK is specified and the line overruns the right
240: * margin, it will break and pad-right to the right margin after
241: * writing. If maxrmargin is violated, it will break and continue
242: * writing from the right-margin, which will lead to the above
243: * scenario upon exit.
244: *
245: * Otherwise, the line will break at the right margin. Extremely long
246: * lines will cause the system to emit a warning (TODO: hyphenate, if
247: * possible).
248: */
1.3 kristaps 249: void
250: flushln(struct termp *p)
251: {
1.25 kristaps 252: size_t i, j, vsz, vis, maxvis, mmax, bp;
1.3 kristaps 253:
254: /*
255: * First, establish the maximum columns of "visible" content.
256: * This is usually the difference between the right-margin and
257: * an indentation, but can be, for tagged lists or columns, a
258: * small set of values.
259: */
260:
261: assert(p->offset < p->rmargin);
262: maxvis = p->rmargin - p->offset;
1.25 kristaps 263: mmax = p->maxrmargin - p->offset;
264: bp = TERMP_NOBREAK & p->flags ? mmax : maxvis;
1.3 kristaps 265: vis = 0;
266:
267: /*
268: * If in the standard case (left-justified), then begin with our
269: * indentation, otherwise (columns, etc.) just start spitting
270: * out text.
271: */
272:
273: if ( ! (p->flags & TERMP_NOLPAD))
274: /* LINTED */
275: for (j = 0; j < p->offset; j++)
276: putchar(' ');
277:
278: for (i = 0; i < p->col; i++) {
279: /*
280: * Count up visible word characters. Control sequences
1.23 kristaps 281: * (starting with the CSI) aren't counted. A space
282: * generates a non-printing word, which is valid (the
283: * space is printed according to regular spacing rules).
1.3 kristaps 284: */
285:
1.25 kristaps 286: /* FIXME: make non-ANSI friendly. */
287:
1.3 kristaps 288: /* LINTED */
289: for (j = i, vsz = 0; j < p->col; j++) {
1.25 kristaps 290: if (isspace((int)p->buf[j]))
1.3 kristaps 291: break;
292: else if (27 == p->buf[j]) {
293: assert(j + 4 <= p->col);
294: j += 3;
295: } else
296: vsz++;
297: }
298:
299: /*
1.25 kristaps 300: * Do line-breaking. If we're greater than our
301: * break-point and already in-line, break to the next
302: * line and start writing. If we're at the line start,
303: * then write out the word (TODO: hyphenate) and break
304: * in a subsequent loop invocation.
1.3 kristaps 305: */
306:
1.22 kristaps 307: if ( ! (TERMP_NOBREAK & p->flags)) {
1.25 kristaps 308: if (vis && vis + vsz > bp) {
1.22 kristaps 309: putchar('\n');
310: for (j = 0; j < p->offset; j++)
311: putchar(' ');
312: vis = 0;
1.25 kristaps 313: } else if (vis + vsz > bp)
314: warnx("word breaks right margin");
315:
316: /* TODO: hyphenate. */
317:
318: } else {
319: if (vis && vis + vsz > bp) {
320: putchar('\n');
321: for (j = 0; j < p->rmargin; j++)
322: putchar(' ');
1.30 kristaps 323: vis = p->rmargin - p->offset;
1.25 kristaps 324: } else if (vis + vsz > bp)
325: warnx("word breaks right margin");
326:
327: /* TODO: hyphenate. */
1.24 kristaps 328: }
1.3 kristaps 329:
330: /*
331: * Write out the word and a trailing space. Omit the
1.25 kristaps 332: * space if we're the last word in the line or beyond
333: * our breakpoint.
1.3 kristaps 334: */
335:
336: for ( ; i < p->col; i++) {
1.25 kristaps 337: if (isspace((int)p->buf[i]))
1.3 kristaps 338: break;
339: putchar(p->buf[i]);
340: }
341: vis += vsz;
1.25 kristaps 342: if (i < p->col && vis <= bp) {
1.3 kristaps 343: putchar(' ');
344: vis++;
345: }
346: }
347:
1.25 kristaps 348: /*
349: * If we've overstepped our maximum visible no-break space, then
350: * cause a newline and offset at the right margin.
351: */
352:
1.22 kristaps 353: if ((TERMP_NOBREAK & p->flags) && vis >= maxvis) {
1.32 ! kristaps 354: if ( ! (TERMP_NONOBREAK & p->flags)) {
! 355: putchar('\n');
! 356: for (i = 0; i < p->rmargin; i++)
! 357: putchar(' ');
! 358: }
1.22 kristaps 359: p->col = 0;
360: return;
361: }
362:
1.3 kristaps 363: /*
364: * If we're not to right-marginalise it (newline), then instead
365: * pad to the right margin and stay off.
366: */
367:
1.32 ! kristaps 368: if (p->flags & TERMP_NOBREAK) {
! 369: if ( ! (TERMP_NONOBREAK & p->flags))
! 370: for ( ; vis < maxvis; vis++)
! 371: putchar(' ');
! 372: } else
1.3 kristaps 373: putchar('\n');
374:
375: p->col = 0;
376: }
377:
378:
1.25 kristaps 379: /*
380: * A newline only breaks an existing line; it won't assert vertical
381: * space. All data in the output buffer is flushed prior to the newline
382: * assertion.
383: */
1.3 kristaps 384: void
385: newln(struct termp *p)
386: {
1.1 kristaps 387:
1.3 kristaps 388: p->flags |= TERMP_NOSPACE;
1.12 kristaps 389: if (0 == p->col) {
390: p->flags &= ~TERMP_NOLPAD;
1.3 kristaps 391: return;
1.12 kristaps 392: }
1.3 kristaps 393: flushln(p);
1.11 kristaps 394: p->flags &= ~TERMP_NOLPAD;
1.3 kristaps 395: }
396:
397:
1.25 kristaps 398: /*
399: * Asserts a vertical space (a full, empty line-break between lines).
400: * Note that if used twice, this will cause two blank spaces and so on.
401: * All data in the output buffer is flushed prior to the newline
402: * assertion.
403: */
1.3 kristaps 404: void
405: vspace(struct termp *p)
406: {
407:
408: newln(p);
409: putchar('\n');
410: }
411:
412:
1.25 kristaps 413: /*
414: * Break apart a word into "pwords" (partial-words, usually from
415: * breaking up a phrase into individual words) and, eventually, put them
416: * into the output buffer. If we're a literal word, then don't break up
417: * the word and put it verbatim into the output buffer.
418: */
1.3 kristaps 419: void
420: word(struct termp *p, const char *word)
421: {
422: size_t i, j, len;
423:
424: if (p->flags & TERMP_LITERAL) {
425: pword(p, word, strlen(word));
426: return;
427: }
428:
429: len = strlen(word);
430: assert(len > 0);
431:
432: if (mdoc_isdelim(word)) {
433: if ( ! (p->flags & TERMP_IGNDELIM))
434: p->flags |= TERMP_NOSPACE;
435: p->flags &= ~TERMP_IGNDELIM;
436: }
437:
438: /* LINTED */
439: for (j = i = 0; i < len; i++) {
1.25 kristaps 440: if ( ! isspace((int)word[i])) {
1.3 kristaps 441: j++;
442: continue;
1.20 kristaps 443: }
444:
445: /* Escaped spaces don't delimit... */
1.25 kristaps 446: if (i > 0 && isspace((int)word[i]) &&
447: '\\' == word[i - 1]) {
1.20 kristaps 448: j++;
449: continue;
1.1 kristaps 450: }
1.20 kristaps 451:
1.3 kristaps 452: if (0 == j)
453: continue;
454: assert(i >= j);
455: pword(p, &word[i - j], j);
456: j = 0;
457: }
458: if (j > 0) {
459: assert(i >= j);
460: pword(p, &word[i - j], j);
461: }
462: }
463:
464:
1.25 kristaps 465: /*
466: * This is the main function for printing out nodes. It's constituted
467: * of PRE and POST functions, which correspond to prefix and infix
468: * processing. The termpair structure allows data to persist between
469: * prefix and postfix invocations.
470: */
1.3 kristaps 471: static void
1.12 kristaps 472: body(struct termp *p, struct termpair *ppair,
473: const struct mdoc_meta *meta,
1.3 kristaps 474: const struct mdoc_node *node)
475: {
476: int dochild;
1.9 kristaps 477: struct termpair pair;
1.3 kristaps 478:
479: /* Pre-processing. */
480:
481: dochild = 1;
1.12 kristaps 482: pair.ppair = ppair;
1.9 kristaps 483: pair.type = 0;
1.11 kristaps 484: pair.offset = pair.rmargin = 0;
1.10 kristaps 485: pair.flag = 0;
1.12 kristaps 486: pair.count = 0;
1.3 kristaps 487:
488: if (MDOC_TEXT != node->type) {
489: if (termacts[node->tok].pre)
1.9 kristaps 490: if ( ! (*termacts[node->tok].pre)(p, &pair, meta, node))
1.3 kristaps 491: dochild = 0;
492: } else /* MDOC_TEXT == node->type */
493: word(p, node->data.text.string);
494:
495: /* Children. */
496:
1.10 kristaps 497: if (TERMPAIR_FLAG & pair.type)
498: p->flags |= pair.flag;
1.9 kristaps 499:
1.3 kristaps 500: if (dochild && node->child)
1.12 kristaps 501: body(p, &pair, meta, node->child);
1.3 kristaps 502:
1.10 kristaps 503: if (TERMPAIR_FLAG & pair.type)
504: p->flags &= ~pair.flag;
1.9 kristaps 505:
1.3 kristaps 506: /* Post-processing. */
507:
508: if (MDOC_TEXT != node->type)
509: if (termacts[node->tok].post)
1.9 kristaps 510: (*termacts[node->tok].post)(p, &pair, meta, node);
1.3 kristaps 511:
512: /* Siblings. */
1.1 kristaps 513:
1.3 kristaps 514: if (node->next)
1.12 kristaps 515: body(p, ppair, meta, node->next);
1.3 kristaps 516: }
517:
518:
519: static void
520: footer(struct termp *p, const struct mdoc_meta *meta)
521: {
522: struct tm *tm;
523: char *buf, *os;
524:
525: if (NULL == (buf = malloc(p->rmargin)))
526: err(1, "malloc");
527: if (NULL == (os = malloc(p->rmargin)))
528: err(1, "malloc");
529:
530: tm = localtime(&meta->date);
531:
1.7 kristaps 532: #ifdef __OpenBSD__
533: if (NULL == strftime(buf, p->rmargin, "%B %d, %Y", tm))
534: #else
1.3 kristaps 535: if (0 == strftime(buf, p->rmargin, "%B %d, %Y", tm))
536: #endif
537: err(1, "strftime");
538:
1.15 kristaps 539: (void)strlcpy(os, meta->os, p->rmargin);
1.3 kristaps 540:
1.16 kristaps 541: /*
542: * This is /slightly/ different from regular groff output
543: * because we don't have page numbers. Print the following:
544: *
545: * OS MDOCDATE
546: */
547:
1.15 kristaps 548: vspace(p);
1.3 kristaps 549:
1.15 kristaps 550: p->flags |= TERMP_NOSPACE | TERMP_NOBREAK;
551: p->rmargin = p->maxrmargin - strlen(buf);
552: p->offset = 0;
1.3 kristaps 553:
1.15 kristaps 554: word(p, os);
555: flushln(p);
1.3 kristaps 556:
1.15 kristaps 557: p->flags |= TERMP_NOLPAD | TERMP_NOSPACE;
558: p->offset = p->rmargin;
559: p->rmargin = p->maxrmargin;
560: p->flags &= ~TERMP_NOBREAK;
561:
562: word(p, buf);
563: flushln(p);
1.1 kristaps 564:
1.3 kristaps 565: free(buf);
566: free(os);
1.1 kristaps 567: }
568:
569:
1.3 kristaps 570: static void
571: header(struct termp *p, const struct mdoc_meta *meta)
572: {
1.18 kristaps 573: char *buf, *title, *bufp, *vbuf;
1.13 kristaps 574: const char *pp;
1.18 kristaps 575: struct utsname uts;
576:
577: p->rmargin = p->maxrmargin;
578: p->offset = 0;
1.3 kristaps 579:
580: if (NULL == (buf = malloc(p->rmargin)))
581: err(1, "malloc");
582: if (NULL == (title = malloc(p->rmargin)))
583: err(1, "malloc");
1.18 kristaps 584: if (NULL == (vbuf = malloc(p->rmargin)))
585: err(1, "malloc");
1.3 kristaps 586:
1.18 kristaps 587: if (NULL == (pp = mdoc_vol2a(meta->vol))) {
1.3 kristaps 588: switch (meta->msec) {
589: case (MSEC_1):
590: /* FALLTHROUGH */
591: case (MSEC_6):
592: /* FALLTHROUGH */
593: case (MSEC_7):
594: pp = mdoc_vol2a(VOL_URM);
595: break;
596: case (MSEC_8):
597: pp = mdoc_vol2a(VOL_SMM);
598: break;
599: case (MSEC_2):
600: /* FALLTHROUGH */
601: case (MSEC_3):
602: /* FALLTHROUGH */
603: case (MSEC_4):
604: /* FALLTHROUGH */
605: case (MSEC_5):
606: pp = mdoc_vol2a(VOL_PRM);
607: break;
608: case (MSEC_9):
609: pp = mdoc_vol2a(VOL_KM);
610: break;
611: default:
612: break;
613: }
1.18 kristaps 614: }
615: vbuf[0] = 0;
616:
617: if (pp) {
618: if (-1 == uname(&uts))
619: err(1, "uname");
620: (void)strlcat(vbuf, uts.sysname, p->rmargin);
621: (void)strlcat(vbuf, " ", p->rmargin);
622: } else if (NULL == (pp = mdoc_msec2a(meta->msec)))
623: pp = mdoc_msec2a(MSEC_local);
624:
625: (void)strlcat(vbuf, pp, p->rmargin);
1.3 kristaps 626:
1.16 kristaps 627: /*
628: * The header is strange. It has three components, which are
629: * really two with the first duplicated. It goes like this:
630: *
631: * IDENTIFIER TITLE IDENTIFIER
632: *
633: * The IDENTIFIER is NAME(SECTION), which is the command-name
634: * (if given, or "unknown" if not) followed by the manual page
635: * section. These are given in `Dt'. The TITLE is a free-form
636: * string depending on the manual volume. If not specified, it
637: * switches on the manual section.
638: */
639:
1.13 kristaps 640: if (mdoc_arch2a(meta->arch))
1.16 kristaps 641: (void)snprintf(buf, p->rmargin, "%s (%s)",
1.18 kristaps 642: vbuf, mdoc_arch2a(meta->arch));
1.13 kristaps 643: else
1.18 kristaps 644: (void)strlcpy(buf, vbuf, p->rmargin);
1.13 kristaps 645:
646: pp = mdoc_msec2a(meta->msec);
647:
648: (void)snprintf(title, p->rmargin, "%s(%s)",
649: meta->title, pp ? pp : "");
650:
1.16 kristaps 651: for (bufp = title; *bufp; bufp++)
652: *bufp = toupper(*bufp);
653:
1.13 kristaps 654: p->offset = 0;
655: p->rmargin = (p->maxrmargin - strlen(buf)) / 2;
1.15 kristaps 656: p->flags |= TERMP_NOBREAK | TERMP_NOSPACE;
1.3 kristaps 657:
1.13 kristaps 658: word(p, title);
659: flushln(p);
1.3 kristaps 660:
1.15 kristaps 661: p->flags |= TERMP_NOLPAD | TERMP_NOSPACE;
1.13 kristaps 662: p->offset = p->rmargin;
1.15 kristaps 663: p->rmargin = p->maxrmargin - strlen(title);
1.3 kristaps 664:
1.13 kristaps 665: word(p, buf);
666: flushln(p);
1.3 kristaps 667:
1.13 kristaps 668: p->offset = p->rmargin;
669: p->rmargin = p->maxrmargin;
670: p->flags &= ~TERMP_NOBREAK;
1.15 kristaps 671: p->flags |= TERMP_NOLPAD | TERMP_NOSPACE;
1.3 kristaps 672:
1.13 kristaps 673: word(p, title);
674: flushln(p);
1.3 kristaps 675:
1.13 kristaps 676: p->rmargin = p->maxrmargin;
677: p->offset = 0;
678: p->flags &= ~TERMP_NOSPACE;
1.3 kristaps 679:
680: free(title);
1.18 kristaps 681: free(vbuf);
1.3 kristaps 682: free(buf);
683: }
1.25 kristaps 684:
685:
686: /*
687: * Determine the symbol indicated by an escape sequences, that is, one
688: * starting with a backslash. Once done, we pass this value into the
689: * output buffer by way of the symbol table.
690: */
691: static void
692: nescape(struct termp *p, const char *word, size_t len)
693: {
1.27 kristaps 694: struct termenc *enc;
1.25 kristaps 695:
696: switch (len) {
697: case (1):
1.27 kristaps 698: enc = termenc1;
1.25 kristaps 699: break;
700: case (2):
1.27 kristaps 701: enc = termenc2;
1.25 kristaps 702: break;
703: default:
1.27 kristaps 704: warnx("unsupported %zu-byte escape sequence", len);
705: return;
1.25 kristaps 706: }
1.27 kristaps 707:
708: for ( ; enc->enc; enc++)
709: if (0 == memcmp(enc->enc, word, len)) {
710: symbola(p, enc->sym);
711: return;
712: }
713:
714: warnx("unsupported %zu-byte escape sequence", len);
1.25 kristaps 715: }
716:
717:
718: /*
719: * Handle an escape sequence: determine its length and pass it to the
720: * escape-symbol look table. Note that we assume mdoc(3) has validated
721: * the escape sequence (we assert upon badly-formed escape sequences).
722: */
723: static void
724: pescape(struct termp *p, const char *word, size_t *i, size_t len)
725: {
726: size_t j;
727:
728: (*i)++;
729: assert(*i < len);
730:
731: if ('(' == word[*i]) {
732: (*i)++;
733: assert(*i + 1 < len);
734: nescape(p, &word[*i], 2);
735: (*i)++;
736: return;
737:
738: } else if ('*' == word[*i]) {
739: /* XXX - deprecated! */
740: (*i)++;
741: assert(*i < len);
742: switch (word[*i]) {
743: case ('('):
744: (*i)++;
745: assert(*i + 1 < len);
746: nescape(p, &word[*i], 2);
747: (*i)++;
748: return;
749: case ('['):
750: break;
751: default:
752: nescape(p, &word[*i], 1);
753: return;
754: }
755:
756: } else if ('[' != word[*i]) {
757: nescape(p, &word[*i], 1);
758: return;
759: }
760:
761: (*i)++;
762: for (j = 0; word[*i] && ']' != word[*i]; (*i)++, j++)
763: /* Loop... */ ;
764:
765: assert(word[*i]);
766: nescape(p, &word[*i - j], j);
767: }
768:
769:
770: /*
771: * Handle pwords, partial words, which may be either a single word or a
772: * phrase that cannot be broken down (such as a literal string). This
773: * handles word styling.
774: */
775: static void
776: pword(struct termp *p, const char *word, size_t len)
777: {
778: size_t i;
779:
780: if ( ! (TERMP_NOSPACE & p->flags) &&
781: ! (TERMP_LITERAL & p->flags))
782: chara(p, ' ');
783:
784: if ( ! (p->flags & TERMP_NONOSPACE))
785: p->flags &= ~TERMP_NOSPACE;
786:
787: /*
788: * XXX - if literal and underlining, this will underline the
789: * spaces between literal words.
790: */
791:
792: if (p->flags & TERMP_BOLD)
1.26 kristaps 793: stylea(p, TERMSTYLE_BOLD);
1.25 kristaps 794: if (p->flags & TERMP_UNDERLINE)
1.26 kristaps 795: stylea(p, TERMSTYLE_UNDER);
1.25 kristaps 796:
797: for (i = 0; i < len; i++) {
798: if ('\\' == word[i]) {
799: pescape(p, word, &i, len);
800: continue;
801: }
802: chara(p, word[i]);
803: }
804:
805: if (p->flags & TERMP_BOLD ||
806: p->flags & TERMP_UNDERLINE)
1.26 kristaps 807: stylea(p, TERMSTYLE_CLEAR);
1.25 kristaps 808: }
809:
810:
811: /*
812: * Add a symbol to the output line buffer.
813: */
814: static void
815: symbola(struct termp *p, enum tsym sym)
816: {
817:
818: assert(p->symtab[sym].sym);
819: stringa(p, p->symtab[sym].sym, p->symtab[sym].sz);
820: }
821:
822:
823: /*
1.26 kristaps 824: * Add a style to the output line buffer.
825: */
826: static void
827: stylea(struct termp *p, enum tstyle style)
828: {
829:
830: assert(p->styletab[style].sym);
831: stringa(p, p->styletab[style].sym, p->styletab[style].sz);
832: }
833:
834:
835: /*
1.25 kristaps 836: * Like chara() but for arbitrary-length buffers. Resize the buffer by
837: * a factor of two (if the buffer is less than that) or the buffer's
838: * size.
839: */
840: static void
841: stringa(struct termp *p, const char *c, size_t sz)
842: {
843: size_t s;
844:
1.27 kristaps 845: if (0 == sz)
846: return;
847:
1.25 kristaps 848: s = sz > p->maxcols * 2 ? sz : p->maxcols * 2;
849:
850: assert(c);
851: if (p->col + sz >= p->maxcols) {
852: p->buf = realloc(p->buf, s);
853: if (NULL == p->buf)
854: err(1, "realloc");
855: p->maxcols = s;
856: }
857:
858: (void)memcpy(&p->buf[p->col], c, sz);
859: p->col += sz;
860: }
861:
862:
863: /*
864: * Insert a single character into the line-buffer. If the buffer's
865: * space is exceeded, then allocate more space by doubling the buffer
866: * size.
867: */
868: static void
869: chara(struct termp *p, char c)
870: {
871:
872: if (p->col + 1 >= p->maxcols) {
873: p->buf = realloc(p->buf, p->maxcols * 2);
874: if (NULL == p->buf)
875: err(1, "malloc");
876: p->maxcols *= 2;
877: }
878: p->buf[(p->col)++] = c;
879: }
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