/* $Id$ */
/*
* Copyright (c) 2008, 2009 Kristaps Dzonsons <kristaps@openbsd.org>
*
* 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 <assert.h>
#include <err.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "term.h"
#ifdef __linux__
extern size_t strlcpy(char *, const char *, size_t);
extern size_t strlcat(char *, const char *, size_t);
#endif
static struct termp *term_alloc(enum termenc);
static void term_free(struct termp *);
static void term_body(struct termp *, struct termpair *,
const struct mdoc_meta *,
const struct mdoc_node *);
static void term_head(struct termp *,
const struct mdoc_meta *);
static void term_foot(struct termp *,
const struct mdoc_meta *);
static void term_pword(struct termp *, const char *, int);
static void term_pescape(struct termp *,
const char *, int *, int);
static void term_nescape(struct termp *,
const char *, size_t);
static void term_chara(struct termp *, char);
static void term_stringa(struct termp *,
const char *, size_t);
static int term_isopendelim(const char *, size_t);
static int term_isclosedelim(const char *, size_t);
static void sanity(const struct mdoc_node *); /* XXX */
void *
latin1_alloc(void)
{
return(term_alloc(TERMENC_LATIN1));
}
void *
utf8_alloc(void)
{
return(term_alloc(TERMENC_UTF8));
}
void *
ascii_alloc(void)
{
return(term_alloc(TERMENC_ASCII));
}
int
terminal_run(void *arg, const struct mdoc *mdoc)
{
struct termp *p;
p = (struct termp *)arg;
if (NULL == p->symtab)
p->symtab = term_ascii2htab();
term_head(p, mdoc_meta(mdoc));
term_body(p, NULL, mdoc_meta(mdoc), mdoc_node(mdoc));
term_foot(p, mdoc_meta(mdoc));
return(1);
}
void
terminal_free(void *arg)
{
term_free((struct termp *)arg);
}
static void
term_free(struct termp *p)
{
if (p->buf)
free(p->buf);
if (TERMENC_ASCII == p->enc && p->symtab)
term_asciifree(p->symtab);
free(p);
}
static struct termp *
term_alloc(enum termenc enc)
{
struct termp *p;
if (NULL == (p = malloc(sizeof(struct termp))))
err(1, "malloc");
bzero(p, sizeof(struct termp));
p->maxrmargin = 78;
p->enc = enc;
return(p);
}
static int
term_isclosedelim(const char *p, size_t len)
{
if (1 != len)
return(0);
switch (*p) {
case('.'):
/* FALLTHROUGH */
case(','):
/* FALLTHROUGH */
case(';'):
/* FALLTHROUGH */
case(':'):
/* FALLTHROUGH */
case('?'):
/* FALLTHROUGH */
case('!'):
/* FALLTHROUGH */
case(')'):
/* FALLTHROUGH */
case(']'):
/* FALLTHROUGH */
case('}'):
return(1);
default:
break;
}
return(0);
}
static int
term_isopendelim(const char *p, size_t len)
{
if (1 != len)
return(0);
switch (*p) {
case('('):
/* FALLTHROUGH */
case('['):
/* FALLTHROUGH */
case('{'):
return(1);
default:
break;
}
return(0);
}
/*
* 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_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.
*
* - TERMP_NONOBREAK: don't newline when TERMP_NOBREAK is specified.
*
* 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
term_flushln(struct termp *p)
{
int i, j;
size_t 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 < (int)p->offset; j++)
putchar(' ');
for (i = 0; i < (int)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).
*/
/* LINTED */
for (j = i, vsz = 0; j < (int)p->col; j++) {
if (' ' == p->buf[j])
break;
else if (8 == p->buf[j])
j += 1;
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 < (int)p->offset; j++)
putchar(' ');
vis = 0;
}
} else if (vis && vis + vsz > bp) {
putchar('\n');
for (j = 0; j < (int)p->rmargin; j++)
putchar(' ');
vis = p->rmargin - p->offset;
}
/*
* 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 < (int)p->col; i++) {
if (' ' == p->buf[i])
break;
putchar(p->buf[i]);
}
vis += vsz;
if (i < (int)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) {
if ( ! (TERMP_NONOBREAK & p->flags)) {
putchar('\n');
for (i = 0; i < (int)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) {
if ( ! (TERMP_NONOBREAK & p->flags))
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
term_newln(struct termp *p)
{
p->flags |= TERMP_NOSPACE;
if (0 == p->col) {
p->flags &= ~TERMP_NOLPAD;
return;
}
term_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
term_vspace(struct termp *p)
{
term_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
term_word(struct termp *p, const char *word)
{
int i, j, len;
len = (int)strlen(word);
if (p->flags & TERMP_LITERAL) {
term_pword(p, word, len);
return;
}
/* LINTED */
for (j = i = 0; i < len; i++) {
if (' ' != word[i]) {
j++;
continue;
}
/* Escaped spaces don't delimit... */
if (i && ' ' == word[i] && '\\' == word[i - 1]) {
j++;
continue;
}
if (0 == j)
continue;
assert(i >= j);
term_pword(p, &word[i - j], j);
j = 0;
}
if (j > 0) {
assert(i >= j);
term_pword(p, &word[i - j], j);
}
}
static void
term_body(struct termp *p, struct termpair *ppair,
const struct mdoc_meta *meta,
const struct mdoc_node *node)
{
term_node(p, ppair, meta, node);
if (node->next)
term_body(p, ppair, meta, node->next);
}
/*
* 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.
*/
void
term_node(struct termp *p, struct termpair *ppair,
const struct mdoc_meta *meta,
const struct mdoc_node *node)
{
int dochild;
struct termpair pair;
/* Some quick sanity-checking. */
sanity(node);
/* 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 */
term_word(p, node->string);
/* Children. */
if (TERMPAIR_FLAG & pair.type)
p->flags |= pair.flag;
if (dochild && node->child)
term_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);
}
static void
term_foot(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
*/
term_vspace(p);
p->flags |= TERMP_NOSPACE | TERMP_NOBREAK;
p->rmargin = p->maxrmargin - strlen(buf);
p->offset = 0;
term_word(p, os);
term_flushln(p);
p->flags |= TERMP_NOLPAD | TERMP_NOSPACE;
p->offset = p->rmargin;
p->rmargin = p->maxrmargin;
p->flags &= ~TERMP_NOBREAK;
term_word(p, buf);
term_flushln(p);
free(buf);
free(os);
}
static void
term_head(struct termp *p, const struct mdoc_meta *meta)
{
char *buf, *title;
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");
/*
* 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.
*/
assert(meta->vol);
(void)strlcpy(buf, meta->vol, p->rmargin);
if (meta->arch) {
(void)strlcat(buf, " (", p->rmargin);
(void)strlcat(buf, meta->arch, p->rmargin);
(void)strlcat(buf, ")", p->rmargin);
}
(void)snprintf(title, p->rmargin, "%s(%d)",
meta->title, meta->msec);
p->offset = 0;
p->rmargin = (p->maxrmargin - strlen(buf)) / 2;
p->flags |= TERMP_NOBREAK | TERMP_NOSPACE;
term_word(p, title);
term_flushln(p);
p->flags |= TERMP_NOLPAD | TERMP_NOSPACE;
p->offset = p->rmargin;
p->rmargin = p->maxrmargin - strlen(title);
term_word(p, buf);
term_flushln(p);
p->offset = p->rmargin;
p->rmargin = p->maxrmargin;
p->flags &= ~TERMP_NOBREAK;
p->flags |= TERMP_NOLPAD | TERMP_NOSPACE;
term_word(p, title);
term_flushln(p);
p->rmargin = p->maxrmargin;
p->offset = 0;
p->flags &= ~TERMP_NOSPACE;
free(title);
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
term_nescape(struct termp *p, const char *word, size_t len)
{
const char *rhs;
size_t sz;
if (NULL == (rhs = term_a2ascii(p->symtab, word, len, &sz)))
return;
term_stringa(p, rhs, sz);
}
/*
* 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
term_pescape(struct termp *p, const char *word, int *i, int len)
{
int j;
if (++(*i) >= len)
return;
if ('(' == word[*i]) {
(*i)++;
if (*i + 1 >= len)
return;
term_nescape(p, &word[*i], 2);
(*i)++;
return;
} else if ('*' == word[*i]) {
(*i)++;
if (*i >= len)
return;
switch (word[*i]) {
case ('('):
(*i)++;
if (*i + 1 >= len)
return;
term_nescape(p, &word[*i], 2);
(*i)++;
return;
case ('['):
break;
default:
term_nescape(p, &word[*i], 1);
return;
}
} else if ('[' != word[*i]) {
term_nescape(p, &word[*i], 1);
return;
}
(*i)++;
for (j = 0; word[*i] && ']' != word[*i]; (*i)++, j++)
/* Loop... */ ;
if (0 == word[*i])
return;
term_nescape(p, &word[*i - j], (size_t)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
term_pword(struct termp *p, const char *word, int len)
{
int i;
if (term_isclosedelim(word, len))
if ( ! (TERMP_IGNDELIM & p->flags))
p->flags |= TERMP_NOSPACE;
if ( ! (TERMP_NOSPACE & p->flags))
term_chara(p, ' ');
if ( ! (p->flags & TERMP_NONOSPACE))
p->flags &= ~TERMP_NOSPACE;
/*
* If ANSI (word-length styling), then apply our style now,
* before the word.
*/
for (i = 0; i < len; i++) {
if ('\\' == word[i]) {
term_pescape(p, word, &i, len);
continue;
}
if (TERMP_STYLE & p->flags) {
if (TERMP_BOLD & p->flags) {
term_chara(p, word[i]);
term_chara(p, 8);
}
if (TERMP_UNDER & p->flags) {
term_chara(p, '_');
term_chara(p, 8);
}
}
term_chara(p, word[i]);
}
if (term_isopendelim(word, len))
p->flags |= TERMP_NOSPACE;
}
/*
* Like term_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
term_stringa(struct termp *p, const char *c, size_t sz)
{
size_t s;
if (0 == sz)
return;
assert(c);
if (p->col + sz >= p->maxcols) {
if (0 == p->maxcols)
p->maxcols = 256;
s = sz > p->maxcols * 2 ? sz : p->maxcols * 2;
p->buf = realloc(p->buf, s);
if (NULL == p->buf)
err(1, "realloc");
p->maxcols = s;
}
(void)memcpy(&p->buf[(int)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
term_chara(struct termp *p, char c)
{
size_t s;
if (p->col + 1 >= p->maxcols) {
if (0 == p->maxcols)
p->maxcols = 256;
s = p->maxcols * 2;
p->buf = realloc(p->buf, s);
if (NULL == p->buf)
err(1, "realloc");
p->maxcols = s;
}
p->buf[(int)(p->col)++] = c;
}
static void
sanity(const struct mdoc_node *n)
{
switch (n->type) {
case (MDOC_TEXT):
if (n->child)
errx(1, "regular form violated (1)");
if (NULL == n->parent)
errx(1, "regular form violated (2)");
if (NULL == n->string)
errx(1, "regular form violated (3)");
switch (n->parent->type) {
case (MDOC_TEXT):
/* FALLTHROUGH */
case (MDOC_ROOT):
errx(1, "regular form violated (4)");
/* NOTREACHED */
default:
break;
}
break;
case (MDOC_ELEM):
if (NULL == n->parent)
errx(1, "regular form violated (5)");
switch (n->parent->type) {
case (MDOC_TAIL):
/* FALLTHROUGH */
case (MDOC_BODY):
/* FALLTHROUGH */
case (MDOC_HEAD):
break;
default:
errx(1, "regular form violated (6)");
/* NOTREACHED */
}
if (n->child) switch (n->child->type) {
case (MDOC_TEXT):
break;
default:
errx(1, "regular form violated (7(");
/* NOTREACHED */
}
break;
case (MDOC_HEAD):
/* FALLTHROUGH */
case (MDOC_BODY):
/* FALLTHROUGH */
case (MDOC_TAIL):
if (NULL == n->parent)
errx(1, "regular form violated (8)");
if (MDOC_BLOCK != n->parent->type)
errx(1, "regular form violated (9)");
if (n->child) switch (n->child->type) {
case (MDOC_BLOCK):
/* FALLTHROUGH */
case (MDOC_ELEM):
/* FALLTHROUGH */
case (MDOC_TEXT):
break;
default:
errx(1, "regular form violated (a)");
/* NOTREACHED */
}
break;
case (MDOC_BLOCK):
if (NULL == n->parent)
errx(1, "regular form violated (b)");
if (NULL == n->child)
errx(1, "regular form violated (c)");
switch (n->parent->type) {
case (MDOC_ROOT):
/* FALLTHROUGH */
case (MDOC_HEAD):
/* FALLTHROUGH */
case (MDOC_BODY):
/* FALLTHROUGH */
case (MDOC_TAIL):
break;
default:
errx(1, "regular form violated (d)");
/* NOTREACHED */
}
switch (n->child->type) {
case (MDOC_ROOT):
/* FALLTHROUGH */
case (MDOC_ELEM):
errx(1, "regular form violated (e)");
/* NOTREACHED */
default:
break;
}
break;
case (MDOC_ROOT):
if (n->parent)
errx(1, "regular form violated (f)");
if (NULL == n->child)
errx(1, "regular form violated (10)");
switch (n->child->type) {
case (MDOC_BLOCK):
break;
default:
errx(1, "regular form violated (11)");
/* NOTREACHED */
}
break;
}
}