/* $Id$ */
/*
* Copyright (c) 2008, 2009, 2010, 2011 Kristaps Dzonsons <kristaps@bsd.lv>
*
* 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.
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <sys/types.h>
#include <assert.h>
#include <stdarg.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include "man.h"
#include "mandoc.h"
#include "libman.h"
#include "libmandoc.h"
const char *const __man_macronames[MAN_MAX] = {
"br", "TH", "SH", "SS",
"TP", "LP", "PP", "P",
"IP", "HP", "SM", "SB",
"BI", "IB", "BR", "RB",
"R", "B", "I", "IR",
"RI", "na", "sp", "nf",
"fi", "RE", "RS", "DT",
"UC", "PD", "AT", "in",
"ft"
};
const char * const *man_macronames = __man_macronames;
static struct man_node *man_node_alloc(struct man *, int, int,
enum man_type, enum mant);
static int man_node_append(struct man *,
struct man_node *);
static void man_node_free(struct man_node *);
static void man_node_unlink(struct man *,
struct man_node *);
static int man_ptext(struct man *, int, char *, int);
static int man_pmacro(struct man *, int, char *, int);
static void man_free1(struct man *);
static void man_alloc1(struct man *);
static int man_descope(struct man *, int, int);
const struct man_node *
man_node(const struct man *m)
{
assert( ! (MAN_HALT & m->flags));
return(m->first);
}
const struct man_meta *
man_meta(const struct man *m)
{
assert( ! (MAN_HALT & m->flags));
return(&m->meta);
}
void
man_reset(struct man *man)
{
man_free1(man);
man_alloc1(man);
}
void
man_free(struct man *man)
{
man_free1(man);
free(man);
}
struct man *
man_alloc(struct roff *roff, struct mparse *parse)
{
struct man *p;
p = mandoc_calloc(1, sizeof(struct man));
man_hash_init();
p->parse = parse;
p->roff = roff;
man_alloc1(p);
return(p);
}
int
man_endparse(struct man *m)
{
assert( ! (MAN_HALT & m->flags));
if (man_macroend(m))
return(1);
m->flags |= MAN_HALT;
return(0);
}
int
man_parseln(struct man *m, int ln, char *buf, int offs)
{
m->flags |= MAN_NEWLINE;
assert( ! (MAN_HALT & m->flags));
return (mandoc_getcontrol(buf, &offs) ?
man_pmacro(m, ln, buf, offs) :
man_ptext(m, ln, buf, offs));
}
static void
man_free1(struct man *man)
{
if (man->first)
man_node_delete(man, man->first);
if (man->meta.title)
free(man->meta.title);
if (man->meta.source)
free(man->meta.source);
if (man->meta.date)
free(man->meta.date);
if (man->meta.vol)
free(man->meta.vol);
if (man->meta.msec)
free(man->meta.msec);
}
static void
man_alloc1(struct man *m)
{
memset(&m->meta, 0, sizeof(struct man_meta));
m->flags = 0;
m->last = mandoc_calloc(1, sizeof(struct man_node));
m->first = m->last;
m->last->type = MAN_ROOT;
m->last->tok = MAN_MAX;
m->next = MAN_NEXT_CHILD;
}
static int
man_node_append(struct man *man, struct man_node *p)
{
assert(man->last);
assert(man->first);
assert(MAN_ROOT != p->type);
switch (man->next) {
case (MAN_NEXT_SIBLING):
man->last->next = p;
p->prev = man->last;
p->parent = man->last->parent;
break;
case (MAN_NEXT_CHILD):
man->last->child = p;
p->parent = man->last;
break;
default:
abort();
/* NOTREACHED */
}
assert(p->parent);
p->parent->nchild++;
if ( ! man_valid_pre(man, p))
return(0);
switch (p->type) {
case (MAN_HEAD):
assert(MAN_BLOCK == p->parent->type);
p->parent->head = p;
break;
case (MAN_TAIL):
assert(MAN_BLOCK == p->parent->type);
p->parent->tail = p;
break;
case (MAN_BODY):
assert(MAN_BLOCK == p->parent->type);
p->parent->body = p;
break;
default:
break;
}
man->last = p;
switch (p->type) {
case (MAN_TBL):
/* FALLTHROUGH */
case (MAN_TEXT):
if ( ! man_valid_post(man))
return(0);
break;
default:
break;
}
return(1);
}
static struct man_node *
man_node_alloc(struct man *m, int line, int pos,
enum man_type type, enum mant tok)
{
struct man_node *p;
p = mandoc_calloc(1, sizeof(struct man_node));
p->line = line;
p->pos = pos;
p->type = type;
p->tok = tok;
if (MAN_NEWLINE & m->flags)
p->flags |= MAN_LINE;
m->flags &= ~MAN_NEWLINE;
return(p);
}
int
man_elem_alloc(struct man *m, int line, int pos, enum mant tok)
{
struct man_node *p;
p = man_node_alloc(m, line, pos, MAN_ELEM, tok);
if ( ! man_node_append(m, p))
return(0);
m->next = MAN_NEXT_CHILD;
return(1);
}
int
man_tail_alloc(struct man *m, int line, int pos, enum mant tok)
{
struct man_node *p;
p = man_node_alloc(m, line, pos, MAN_TAIL, tok);
if ( ! man_node_append(m, p))
return(0);
m->next = MAN_NEXT_CHILD;
return(1);
}
int
man_head_alloc(struct man *m, int line, int pos, enum mant tok)
{
struct man_node *p;
p = man_node_alloc(m, line, pos, MAN_HEAD, tok);
if ( ! man_node_append(m, p))
return(0);
m->next = MAN_NEXT_CHILD;
return(1);
}
int
man_body_alloc(struct man *m, int line, int pos, enum mant tok)
{
struct man_node *p;
p = man_node_alloc(m, line, pos, MAN_BODY, tok);
if ( ! man_node_append(m, p))
return(0);
m->next = MAN_NEXT_CHILD;
return(1);
}
int
man_block_alloc(struct man *m, int line, int pos, enum mant tok)
{
struct man_node *p;
p = man_node_alloc(m, line, pos, MAN_BLOCK, tok);
if ( ! man_node_append(m, p))
return(0);
m->next = MAN_NEXT_CHILD;
return(1);
}
int
man_word_alloc(struct man *m, int line, int pos, const char *word)
{
struct man_node *n;
size_t sv, len;
len = strlen(word);
n = man_node_alloc(m, line, pos, MAN_TEXT, MAN_MAX);
n->string = mandoc_malloc(len + 1);
sv = strlcpy(n->string, word, len + 1);
/* Prohibit truncation. */
assert(sv < len + 1);
if ( ! man_node_append(m, n))
return(0);
m->next = MAN_NEXT_SIBLING;
return(1);
}
/*
* Free all of the resources held by a node. This does NOT unlink a
* node from its context; for that, see man_node_unlink().
*/
static void
man_node_free(struct man_node *p)
{
if (p->string)
free(p->string);
free(p);
}
void
man_node_delete(struct man *m, struct man_node *p)
{
while (p->child)
man_node_delete(m, p->child);
man_node_unlink(m, p);
man_node_free(p);
}
int
man_addeqn(struct man *m, const struct eqn *ep)
{
struct man_node *n;
assert( ! (MAN_HALT & m->flags));
n = man_node_alloc(m, ep->ln, ep->pos, MAN_EQN, MAN_MAX);
n->eqn = ep;
if ( ! man_node_append(m, n))
return(0);
m->next = MAN_NEXT_SIBLING;
return(man_descope(m, ep->ln, ep->pos));
}
int
man_addspan(struct man *m, const struct tbl_span *sp)
{
struct man_node *n;
assert( ! (MAN_HALT & m->flags));
n = man_node_alloc(m, sp->line, 0, MAN_TBL, MAN_MAX);
n->span = sp;
if ( ! man_node_append(m, n))
return(0);
m->next = MAN_NEXT_SIBLING;
return(man_descope(m, sp->line, 0));
}
static int
man_descope(struct man *m, int line, int offs)
{
/*
* Co-ordinate what happens with having a next-line scope open:
* first close out the element scope (if applicable), then close
* out the block scope (also if applicable).
*/
if (MAN_ELINE & m->flags) {
m->flags &= ~MAN_ELINE;
if ( ! man_unscope(m, m->last->parent, MANDOCERR_MAX))
return(0);
}
if ( ! (MAN_BLINE & m->flags))
return(1);
m->flags &= ~MAN_BLINE;
if ( ! man_unscope(m, m->last->parent, MANDOCERR_MAX))
return(0);
return(man_body_alloc(m, line, offs, m->last->tok));
}
static int
man_ptext(struct man *m, int line, char *buf, int offs)
{
int i;
/* Literal free-form text whitespace is preserved. */
if (MAN_LITERAL & m->flags) {
if ( ! man_word_alloc(m, line, offs, buf + offs))
return(0);
return(man_descope(m, line, offs));
}
/* Pump blank lines directly into the backend. */
for (i = offs; ' ' == buf[i]; i++)
/* Skip leading whitespace. */ ;
if ('\0' == buf[i]) {
/* Allocate a blank entry. */
if ( ! man_word_alloc(m, line, offs, ""))
return(0);
return(man_descope(m, line, offs));
}
/*
* Warn if the last un-escaped character is whitespace. Then
* strip away the remaining spaces (tabs stay!).
*/
i = (int)strlen(buf);
assert(i);
if (' ' == buf[i - 1] || '\t' == buf[i - 1]) {
if (i > 1 && '\\' != buf[i - 2])
man_pmsg(m, line, i - 1, MANDOCERR_EOLNSPACE);
for (--i; i && ' ' == buf[i]; i--)
/* Spin back to non-space. */ ;
/* Jump ahead of escaped whitespace. */
i += '\\' == buf[i] ? 2 : 1;
buf[i] = '\0';
}
if ( ! man_word_alloc(m, line, offs, buf + offs))
return(0);
/*
* End-of-sentence check. If the last character is an unescaped
* EOS character, then flag the node as being the end of a
* sentence. The front-end will know how to interpret this.
*/
assert(i);
if (mandoc_eos(buf, (size_t)i, 0))
m->last->flags |= MAN_EOS;
return(man_descope(m, line, offs));
}
static int
man_pmacro(struct man *m, int ln, char *buf, int offs)
{
int i, ppos;
enum mant tok;
char mac[5];
struct man_node *n;
if ('"' == buf[offs]) {
man_pmsg(m, ln, offs, MANDOCERR_BADCOMMENT);
return(1);
} else if ('\0' == buf[offs])
return(1);
ppos = offs;
/*
* Copy the first word into a nil-terminated buffer.
* Stop copying when a tab, space, or eoln is encountered.
*/
i = 0;
while (i < 4 && '\0' != buf[offs] &&
' ' != buf[offs] && '\t' != buf[offs])
mac[i++] = buf[offs++];
mac[i] = '\0';
tok = (i > 0 && i < 4) ? man_hash_find(mac) : MAN_MAX;
if (MAN_MAX == tok) {
mandoc_vmsg(MANDOCERR_MACRO, m->parse, ln,
ppos, "%s", buf + ppos - 1);
return(1);
}
/* The macro is sane. Jump to the next word. */
while (buf[offs] && ' ' == buf[offs])
offs++;
/*
* Trailing whitespace. Note that tabs are allowed to be passed
* into the parser as "text", so we only warn about spaces here.
*/
if ('\0' == buf[offs] && ' ' == buf[offs - 1])
man_pmsg(m, ln, offs - 1, MANDOCERR_EOLNSPACE);
/*
* Remove prior ELINE macro, as it's being clobbered by a new
* macro. Note that NSCOPED macros do not close out ELINE
* macros---they don't print text---so we let those slip by.
*/
if ( ! (MAN_NSCOPED & man_macros[tok].flags) &&
m->flags & MAN_ELINE) {
n = m->last;
assert(MAN_TEXT != n->type);
/* Remove repeated NSCOPED macros causing ELINE. */
if (MAN_NSCOPED & man_macros[n->tok].flags)
n = n->parent;
mandoc_vmsg(MANDOCERR_LINESCOPE, m->parse, n->line,
n->pos, "%s", man_macronames[n->tok]);
man_node_delete(m, n);
m->flags &= ~MAN_ELINE;
}
/*
* Save the fact that we're in the next-line for a block. In
* this way, embedded roff instructions can "remember" state
* when they exit.
*/
if (MAN_BLINE & m->flags)
m->flags |= MAN_BPLINE;
/* Call to handler... */
assert(man_macros[tok].fp);
if ( ! (*man_macros[tok].fp)(m, tok, ln, ppos, &offs, buf))
goto err;
/*
* We weren't in a block-line scope when entering the
* above-parsed macro, so return.
*/
if ( ! (MAN_BPLINE & m->flags)) {
m->flags &= ~MAN_ILINE;
return(1);
}
m->flags &= ~MAN_BPLINE;
/*
* If we're in a block scope, then allow this macro to slip by
* without closing scope around it.
*/
if (MAN_ILINE & m->flags) {
m->flags &= ~MAN_ILINE;
return(1);
}
/*
* If we've opened a new next-line element scope, then return
* now, as the next line will close out the block scope.
*/
if (MAN_ELINE & m->flags)
return(1);
/* Close out the block scope opened in the prior line. */
assert(MAN_BLINE & m->flags);
m->flags &= ~MAN_BLINE;
if ( ! man_unscope(m, m->last->parent, MANDOCERR_MAX))
return(0);
return(man_body_alloc(m, ln, ppos, m->last->tok));
err: /* Error out. */
m->flags |= MAN_HALT;
return(0);
}
/*
* Unlink a node from its context. If "m" is provided, the last parse
* point will also be adjusted accordingly.
*/
static void
man_node_unlink(struct man *m, struct man_node *n)
{
/* Adjust siblings. */
if (n->prev)
n->prev->next = n->next;
if (n->next)
n->next->prev = n->prev;
/* Adjust parent. */
if (n->parent) {
n->parent->nchild--;
if (n->parent->child == n)
n->parent->child = n->prev ? n->prev : n->next;
}
/* Adjust parse point, if applicable. */
if (m && m->last == n) {
/*XXX: this can occur when bailing from validation. */
/*assert(NULL == n->next);*/
if (n->prev) {
m->last = n->prev;
m->next = MAN_NEXT_SIBLING;
} else {
m->last = n->parent;
m->next = MAN_NEXT_CHILD;
}
}
if (m && m->first == n)
m->first = NULL;
}