/* $Id$ */ /* * Copyright (c) 2008 Kristaps Dzonsons * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the * above copyright notice and this permission notice appear in all * copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL * WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE * AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL * DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR * PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR * PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #ifndef __OpenBSD__ #include #endif #include "mmain.h" #include "term.h" static void body(struct termp *, struct termpair *, const struct mdoc_meta *, const struct mdoc_node *); static void header(struct termp *, const struct mdoc_meta *); static void footer(struct termp *, const struct mdoc_meta *); static void pword(struct termp *, const char *, size_t); static void pescape(struct termp *, const char *, size_t *, size_t); static void style(struct termp *, enum tstyle); static void nescape(struct termp *, const char *, size_t); static void chara(struct termp *, char); static void stringa(struct termp *, const char *, size_t); static void symbola(struct termp *, enum tsym); #ifdef __linux__ extern size_t strlcat(char *, const char *, size_t); extern size_t strlcpy(char *, const char *, size_t); #endif static struct termsym termsym_ansi[] = { { "]", 1 }, /* TERMSYM_RBRACK */ { "[", 1 }, /* TERMSYM_LBRACK */ { "<-", 2 }, /* TERMSYM_LARROW */ { "->", 2 }, /* TERMSYM_RARROW */ { "^", 1 }, /* TERMSYM_UARROW */ { "v", 1 }, /* TERMSYM_DARROW */ { "`", 1 }, /* TERMSYM_LSQUOTE */ { "\'", 1 }, /* TERMSYM_RSQUOTE */ { "\'", 1 }, /* TERMSYM_SQUOTE */ { "``", 2 }, /* TERMSYM_LDQUOTE */ { "\'\'", 2 }, /* TERMSYM_RDQUOTE */ { "\"", 1 }, /* TERMSYM_DQUOTE */ { "<", 1 }, /* TERMSYM_LT */ { ">", 1 }, /* TERMSYM_GT */ { "<=", 2 }, /* TERMSYM_LE */ { ">=", 2 }, /* TERMSYM_GE */ { "==", 2 }, /* TERMSYM_EQ */ { "!=", 2 }, /* TERMSYM_NEQ */ { "\'", 1 }, /* TERMSYM_ACUTE */ { "`", 1 }, /* TERMSYM_GRAVE */ { "pi", 2 }, /* TERMSYM_PI */ { "+=", 2 }, /* TERMSYM_PLUSMINUS */ { "oo", 2 }, /* TERMSYM_INF */ { "infinity", 8 }, /* TERMSYM_INF2 */ { "NaN", 3 }, /* TERMSYM_NAN */ { "|", 1 }, /* TERMSYM_BAR */ { "o", 1 }, /* TERMSYM_BULLET */ { "&", 1 }, /* TERMSYM_AND */ { "|", 1 }, /* TERMSYM_OR */ }; static const char ansi_clear[] = { 27, '[', '0', 'm' }; static const char ansi_bold[] = { 27, '[', '1', 'm' }; static const char ansi_under[] = { 27, '[', '4', 'm' }; static struct termsym termstyle_ansi[] = { { ansi_clear, 4 }, { ansi_bold, 4 }, { ansi_under, 4 } }; int main(int argc, char *argv[]) { struct mmain *p; const struct mdoc *mdoc; struct termp termp; p = mmain_alloc(); if ( ! mmain_getopt(p, argc, argv, NULL, NULL, NULL, NULL)) mmain_exit(p, 1); if (NULL == (mdoc = mmain_mdoc(p))) mmain_exit(p, 1); termp.maxrmargin = 78; /* XXX */ termp.rmargin = termp.maxrmargin; termp.maxcols = 1024; termp.offset = termp.col = 0; termp.flags = TERMP_NOSPACE; termp.symtab = termsym_ansi; termp.styletab = termstyle_ansi; if (NULL == (termp.buf = malloc(termp.maxcols))) err(1, "malloc"); header(&termp, mdoc_meta(mdoc)); body(&termp, NULL, mdoc_meta(mdoc), mdoc_node(mdoc)); footer(&termp, mdoc_meta(mdoc)); free(termp.buf); mmain_exit(p, 0); /* NOTREACHED */ } /* * Flush a line of text. A "line" is loosely defined as being something * that should be followed by a newline, regardless of whether it's * broken apart by newlines getting there. A line can also be a * fragment of a columnar list. * * Specifically, a line is whatever's in p->buf of length p->col, which * is zeroed after this function returns. * * The variables TERMP_NOLPAD, TERMP_LITERAL and TERMP_NOBREAK are of * critical importance here. Their behaviour follows: * * - TERMP_NOLPAD: when beginning to write the line, don't left-pad the * offset value. This is useful when doing columnar lists where the * prior column has right-padded. * * - TERMP_LITERAL: don't break apart words. Note that a long literal * word will violate the right margin. * * - TERMP_NOBREAK: this is the most important and is used when making * columns. In short: don't print a newline and instead pad to the * right margin. Used in conjunction with TERMP_NOLPAD. * * In-line line breaking: * * If TERMP_NOBREAK is specified and the line overruns the right * margin, it will break and pad-right to the right margin after * writing. If maxrmargin is violated, it will break and continue * writing from the right-margin, which will lead to the above * scenario upon exit. * * Otherwise, the line will break at the right margin. Extremely long * lines will cause the system to emit a warning (TODO: hyphenate, if * possible). */ void flushln(struct termp *p) { size_t i, j, vsz, vis, maxvis, mmax, bp; /* * First, establish the maximum columns of "visible" content. * This is usually the difference between the right-margin and * an indentation, but can be, for tagged lists or columns, a * small set of values. */ assert(p->offset < p->rmargin); maxvis = p->rmargin - p->offset; mmax = p->maxrmargin - p->offset; bp = TERMP_NOBREAK & p->flags ? mmax : maxvis; vis = 0; /* * If in the standard case (left-justified), then begin with our * indentation, otherwise (columns, etc.) just start spitting * out text. */ if ( ! (p->flags & TERMP_NOLPAD)) /* LINTED */ for (j = 0; j < p->offset; j++) putchar(' '); for (i = 0; i < p->col; i++) { /* * Count up visible word characters. Control sequences * (starting with the CSI) aren't counted. A space * generates a non-printing word, which is valid (the * space is printed according to regular spacing rules). */ /* FIXME: make non-ANSI friendly. */ /* LINTED */ for (j = i, vsz = 0; j < p->col; j++) { if (isspace((int)p->buf[j])) break; else if (27 == p->buf[j]) { assert(j + 4 <= p->col); j += 3; } else vsz++; } /* * Do line-breaking. If we're greater than our * break-point and already in-line, break to the next * line and start writing. If we're at the line start, * then write out the word (TODO: hyphenate) and break * in a subsequent loop invocation. */ if ( ! (TERMP_NOBREAK & p->flags)) { if (vis && vis + vsz > bp) { putchar('\n'); for (j = 0; j < p->offset; j++) putchar(' '); vis = 0; } else if (vis + vsz > bp) warnx("word breaks right margin"); /* TODO: hyphenate. */ } else { if (vis && vis + vsz > bp) { putchar('\n'); for (j = 0; j < p->rmargin; j++) putchar(' '); vis = p->rmargin; } else if (vis + vsz > bp) warnx("word breaks right margin"); /* TODO: hyphenate. */ } /* * Write out the word and a trailing space. Omit the * space if we're the last word in the line or beyond * our breakpoint. */ for ( ; i < p->col; i++) { if (isspace((int)p->buf[i])) break; putchar(p->buf[i]); } vis += vsz; if (i < p->col && vis <= bp) { putchar(' '); vis++; } } /* * If we've overstepped our maximum visible no-break space, then * cause a newline and offset at the right margin. */ if ((TERMP_NOBREAK & p->flags) && vis >= maxvis) { putchar('\n'); for (i = 0; i < p->rmargin; i++) putchar(' '); p->col = 0; return; } /* * If we're not to right-marginalise it (newline), then instead * pad to the right margin and stay off. */ if (p->flags & TERMP_NOBREAK) { for ( ; vis < maxvis; vis++) putchar(' '); } else putchar('\n'); p->col = 0; } /* * A newline only breaks an existing line; it won't assert vertical * space. All data in the output buffer is flushed prior to the newline * assertion. */ void newln(struct termp *p) { p->flags |= TERMP_NOSPACE; if (0 == p->col) { p->flags &= ~TERMP_NOLPAD; return; } flushln(p); p->flags &= ~TERMP_NOLPAD; } /* * Asserts a vertical space (a full, empty line-break between lines). * Note that if used twice, this will cause two blank spaces and so on. * All data in the output buffer is flushed prior to the newline * assertion. */ void vspace(struct termp *p) { newln(p); putchar('\n'); } /* * Break apart a word into "pwords" (partial-words, usually from * breaking up a phrase into individual words) and, eventually, put them * into the output buffer. If we're a literal word, then don't break up * the word and put it verbatim into the output buffer. */ void word(struct termp *p, const char *word) { size_t i, j, len; if (p->flags & TERMP_LITERAL) { pword(p, word, strlen(word)); return; } len = strlen(word); assert(len > 0); if (mdoc_isdelim(word)) { if ( ! (p->flags & TERMP_IGNDELIM)) p->flags |= TERMP_NOSPACE; p->flags &= ~TERMP_IGNDELIM; } /* LINTED */ for (j = i = 0; i < len; i++) { if ( ! isspace((int)word[i])) { j++; continue; } /* Escaped spaces don't delimit... */ if (i > 0 && isspace((int)word[i]) && '\\' == word[i - 1]) { j++; continue; } if (0 == j) continue; assert(i >= j); pword(p, &word[i - j], j); j = 0; } if (j > 0) { assert(i >= j); pword(p, &word[i - j], j); } } /* * This is the main function for printing out nodes. It's constituted * of PRE and POST functions, which correspond to prefix and infix * processing. The termpair structure allows data to persist between * prefix and postfix invocations. */ static void body(struct termp *p, struct termpair *ppair, const struct mdoc_meta *meta, const struct mdoc_node *node) { int dochild; struct termpair pair; /* Pre-processing. */ dochild = 1; pair.ppair = ppair; pair.type = 0; pair.offset = pair.rmargin = 0; pair.flag = 0; pair.count = 0; if (MDOC_TEXT != node->type) { if (termacts[node->tok].pre) if ( ! (*termacts[node->tok].pre)(p, &pair, meta, node)) dochild = 0; } else /* MDOC_TEXT == node->type */ word(p, node->data.text.string); /* Children. */ if (TERMPAIR_FLAG & pair.type) p->flags |= pair.flag; if (dochild && node->child) body(p, &pair, meta, node->child); if (TERMPAIR_FLAG & pair.type) p->flags &= ~pair.flag; /* Post-processing. */ if (MDOC_TEXT != node->type) if (termacts[node->tok].post) (*termacts[node->tok].post)(p, &pair, meta, node); /* Siblings. */ if (node->next) body(p, ppair, meta, node->next); } static void footer(struct termp *p, const struct mdoc_meta *meta) { struct tm *tm; char *buf, *os; if (NULL == (buf = malloc(p->rmargin))) err(1, "malloc"); if (NULL == (os = malloc(p->rmargin))) err(1, "malloc"); tm = localtime(&meta->date); #ifdef __OpenBSD__ if (NULL == strftime(buf, p->rmargin, "%B %d, %Y", tm)) #else if (0 == strftime(buf, p->rmargin, "%B %d, %Y", tm)) #endif err(1, "strftime"); (void)strlcpy(os, meta->os, p->rmargin); /* * This is /slightly/ different from regular groff output * because we don't have page numbers. Print the following: * * OS MDOCDATE */ vspace(p); p->flags |= TERMP_NOSPACE | TERMP_NOBREAK; p->rmargin = p->maxrmargin - strlen(buf); p->offset = 0; word(p, os); flushln(p); p->flags |= TERMP_NOLPAD | TERMP_NOSPACE; p->offset = p->rmargin; p->rmargin = p->maxrmargin; p->flags &= ~TERMP_NOBREAK; word(p, buf); flushln(p); free(buf); free(os); } static void header(struct termp *p, const struct mdoc_meta *meta) { char *buf, *title, *bufp, *vbuf; const char *pp; struct utsname uts; p->rmargin = p->maxrmargin; p->offset = 0; if (NULL == (buf = malloc(p->rmargin))) err(1, "malloc"); if (NULL == (title = malloc(p->rmargin))) err(1, "malloc"); if (NULL == (vbuf = malloc(p->rmargin))) err(1, "malloc"); if (NULL == (pp = mdoc_vol2a(meta->vol))) { switch (meta->msec) { case (MSEC_1): /* FALLTHROUGH */ case (MSEC_6): /* FALLTHROUGH */ case (MSEC_7): pp = mdoc_vol2a(VOL_URM); break; case (MSEC_8): pp = mdoc_vol2a(VOL_SMM); break; case (MSEC_2): /* FALLTHROUGH */ case (MSEC_3): /* FALLTHROUGH */ case (MSEC_4): /* FALLTHROUGH */ case (MSEC_5): pp = mdoc_vol2a(VOL_PRM); break; case (MSEC_9): pp = mdoc_vol2a(VOL_KM); break; default: break; } } vbuf[0] = 0; if (pp) { if (-1 == uname(&uts)) err(1, "uname"); (void)strlcat(vbuf, uts.sysname, p->rmargin); (void)strlcat(vbuf, " ", p->rmargin); } else if (NULL == (pp = mdoc_msec2a(meta->msec))) pp = mdoc_msec2a(MSEC_local); (void)strlcat(vbuf, pp, p->rmargin); /* * The header is strange. It has three components, which are * really two with the first duplicated. It goes like this: * * IDENTIFIER TITLE IDENTIFIER * * The IDENTIFIER is NAME(SECTION), which is the command-name * (if given, or "unknown" if not) followed by the manual page * section. These are given in `Dt'. The TITLE is a free-form * string depending on the manual volume. If not specified, it * switches on the manual section. */ if (mdoc_arch2a(meta->arch)) (void)snprintf(buf, p->rmargin, "%s (%s)", vbuf, mdoc_arch2a(meta->arch)); else (void)strlcpy(buf, vbuf, p->rmargin); pp = mdoc_msec2a(meta->msec); (void)snprintf(title, p->rmargin, "%s(%s)", meta->title, pp ? pp : ""); for (bufp = title; *bufp; bufp++) *bufp = toupper(*bufp); p->offset = 0; p->rmargin = (p->maxrmargin - strlen(buf)) / 2; p->flags |= TERMP_NOBREAK | TERMP_NOSPACE; word(p, title); flushln(p); p->flags |= TERMP_NOLPAD | TERMP_NOSPACE; p->offset = p->rmargin; p->rmargin = p->maxrmargin - strlen(title); word(p, buf); flushln(p); p->offset = p->rmargin; p->rmargin = p->maxrmargin; p->flags &= ~TERMP_NOBREAK; p->flags |= TERMP_NOLPAD | TERMP_NOSPACE; word(p, title); flushln(p); p->rmargin = p->maxrmargin; p->offset = 0; p->flags &= ~TERMP_NOSPACE; free(title); free(vbuf); free(buf); } /* * Determine the symbol indicated by an escape sequences, that is, one * starting with a backslash. Once done, we pass this value into the * output buffer by way of the symbol table. */ static void nescape(struct termp *p, const char *word, size_t len) { switch (len) { case (1): switch (word[0]) { case ('\\'): /* FALLTHROUGH */ case ('\''): /* FALLTHROUGH */ case ('`'): /* FALLTHROUGH */ case ('-'): /* FALLTHROUGH */ case (' '): /* FALLTHROUGH */ case ('.'): chara(p, word[0]); /* FIXME */ break; case ('&'): break; case ('e'): chara(p, '\\'); /* FIXME */ break; case ('q'): symbola(p, TERMSYM_DQUOTE); break; default: warnx("escape sequence not supported: %c", word[0]); break; } break; case (2): if ('r' == word[0] && 'B' == word[1]) symbola(p, TERMSYM_RBRACK); else if ('l' == word[0] && 'B' == word[1]) symbola(p, TERMSYM_LBRACK); else if ('l' == word[0] && 'q' == word[1]) symbola(p, TERMSYM_LDQUOTE); else if ('r' == word[0] && 'q' == word[1]) symbola(p, TERMSYM_RDQUOTE); else if ('o' == word[0] && 'q' == word[1]) symbola(p, TERMSYM_LSQUOTE); else if ('a' == word[0] && 'q' == word[1]) symbola(p, TERMSYM_RSQUOTE); else if ('<' == word[0] && '-' == word[1]) symbola(p, TERMSYM_LARROW); else if ('-' == word[0] && '>' == word[1]) symbola(p, TERMSYM_RARROW); else if ('b' == word[0] && 'u' == word[1]) symbola(p, TERMSYM_BULLET); else if ('<' == word[0] && '=' == word[1]) symbola(p, TERMSYM_LE); else if ('>' == word[0] && '=' == word[1]) symbola(p, TERMSYM_GE); else if ('=' == word[0] && '=' == word[1]) symbola(p, TERMSYM_EQ); else if ('+' == word[0] && '-' == word[1]) symbola(p, TERMSYM_PLUSMINUS); else if ('u' == word[0] && 'a' == word[1]) symbola(p, TERMSYM_UARROW); else if ('d' == word[0] && 'a' == word[1]) symbola(p, TERMSYM_DARROW); else if ('a' == word[0] && 'a' == word[1]) symbola(p, TERMSYM_ACUTE); else if ('g' == word[0] && 'a' == word[1]) symbola(p, TERMSYM_GRAVE); else if ('!' == word[0] && '=' == word[1]) symbola(p, TERMSYM_NEQ); else if ('i' == word[0] && 'f' == word[1]) symbola(p, TERMSYM_INF); else if ('n' == word[0] && 'a' == word[1]) symbola(p, TERMSYM_NAN); else if ('b' == word[0] && 'a' == word[1]) symbola(p, TERMSYM_BAR); /* Deprecated forms. */ else if ('A' == word[0] && 'm' == word[1]) symbola(p, TERMSYM_AMP); else if ('B' == word[0] && 'a' == word[1]) symbola(p, TERMSYM_BAR); else if ('I' == word[0] && 'f' == word[1]) symbola(p, TERMSYM_INF2); else if ('G' == word[0] && 'e' == word[1]) symbola(p, TERMSYM_GE); else if ('G' == word[0] && 't' == word[1]) symbola(p, TERMSYM_GT); else if ('L' == word[0] && 'e' == word[1]) symbola(p, TERMSYM_LE); else if ('L' == word[0] && 'q' == word[1]) symbola(p, TERMSYM_LDQUOTE); else if ('L' == word[0] && 't' == word[1]) symbola(p, TERMSYM_LT); else if ('N' == word[0] && 'a' == word[1]) symbola(p, TERMSYM_NAN); else if ('N' == word[0] && 'e' == word[1]) symbola(p, TERMSYM_NEQ); else if ('P' == word[0] && 'i' == word[1]) symbola(p, TERMSYM_PI); else if ('P' == word[0] && 'm' == word[1]) symbola(p, TERMSYM_PLUSMINUS); else if ('R' == word[0] && 'q' == word[1]) symbola(p, TERMSYM_RDQUOTE); else warnx("escape sequence not supported: %c%c", word[0], word[1]); break; default: warnx("escape sequence not supported"); break; } } /* * Apply a style to the output buffer. This is looked up by means of * the styletab. */ static void style(struct termp *p, enum tstyle esc) { if (p->col + 4 >= p->maxcols) errx(1, "line overrun"); p->buf[(p->col)++] = 27; p->buf[(p->col)++] = '['; switch (esc) { case (TERMSTYLE_CLEAR): p->buf[(p->col)++] = '0'; break; case (TERMSTYLE_BOLD): p->buf[(p->col)++] = '1'; break; case (TERMSTYLE_UNDER): p->buf[(p->col)++] = '4'; break; default: abort(); /* NOTREACHED */ } p->buf[(p->col)++] = 'm'; } /* * Handle an escape sequence: determine its length and pass it to the * escape-symbol look table. Note that we assume mdoc(3) has validated * the escape sequence (we assert upon badly-formed escape sequences). */ static void pescape(struct termp *p, const char *word, size_t *i, size_t len) { size_t j; (*i)++; assert(*i < len); if ('(' == word[*i]) { (*i)++; assert(*i + 1 < len); nescape(p, &word[*i], 2); (*i)++; return; } else if ('*' == word[*i]) { /* XXX - deprecated! */ (*i)++; assert(*i < len); switch (word[*i]) { case ('('): (*i)++; assert(*i + 1 < len); nescape(p, &word[*i], 2); (*i)++; return; case ('['): break; default: nescape(p, &word[*i], 1); return; } } else if ('[' != word[*i]) { nescape(p, &word[*i], 1); return; } (*i)++; for (j = 0; word[*i] && ']' != word[*i]; (*i)++, j++) /* Loop... */ ; assert(word[*i]); nescape(p, &word[*i - j], j); } /* * Handle pwords, partial words, which may be either a single word or a * phrase that cannot be broken down (such as a literal string). This * handles word styling. */ static void pword(struct termp *p, const char *word, size_t len) { size_t i; if ( ! (TERMP_NOSPACE & p->flags) && ! (TERMP_LITERAL & p->flags)) chara(p, ' '); if ( ! (p->flags & TERMP_NONOSPACE)) p->flags &= ~TERMP_NOSPACE; /* * XXX - if literal and underlining, this will underline the * spaces between literal words. */ if (p->flags & TERMP_BOLD) style(p, TERMSTYLE_BOLD); if (p->flags & TERMP_UNDERLINE) style(p, TERMSTYLE_UNDER); for (i = 0; i < len; i++) { if ('\\' == word[i]) { pescape(p, word, &i, len); continue; } chara(p, word[i]); } if (p->flags & TERMP_BOLD || p->flags & TERMP_UNDERLINE) style(p, TERMSTYLE_CLEAR); } /* * Add a symbol to the output line buffer. */ static void symbola(struct termp *p, enum tsym sym) { assert(p->symtab[sym].sym); stringa(p, p->symtab[sym].sym, p->symtab[sym].sz); } /* * Like chara() but for arbitrary-length buffers. Resize the buffer by * a factor of two (if the buffer is less than that) or the buffer's * size. */ static void stringa(struct termp *p, const char *c, size_t sz) { size_t s; s = sz > p->maxcols * 2 ? sz : p->maxcols * 2; assert(c); if (p->col + sz >= p->maxcols) { p->buf = realloc(p->buf, s); if (NULL == p->buf) err(1, "realloc"); p->maxcols = s; } (void)memcpy(&p->buf[p->col], c, sz); p->col += sz; } /* * Insert a single character into the line-buffer. If the buffer's * space is exceeded, then allocate more space by doubling the buffer * size. */ static void chara(struct termp *p, char c) { if (p->col + 1 >= p->maxcols) { p->buf = realloc(p->buf, p->maxcols * 2); if (NULL == p->buf) err(1, "malloc"); p->maxcols *= 2; } p->buf[(p->col)++] = c; }