| version 1.11, 2009/03/31 13:50:19 |
version 1.40, 2010/03/27 10:14:32 |
|
|
| /* $Id$ */ |
/* $Id$ */ |
| /* |
/* |
| * Copyright (c) 2008, 2009 Kristaps Dzonsons <kristaps@openbsd.org> |
* Copyright (c) 2008, 2009 Kristaps Dzonsons <kristaps@kth.se> |
| * |
* |
| * Permission to use, copy, modify, and distribute this software for any |
* Permission to use, copy, modify, and distribute this software for any |
| * purpose with or without fee is hereby granted, provided that the |
* purpose with or without fee is hereby granted, provided that the above |
| * above copyright notice and this permission notice appear in all |
* copyright notice and this permission notice appear in all copies. |
| * copies. |
|
| * |
* |
| * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL |
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES |
| * WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED |
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF |
| * WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE |
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR |
| * AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL |
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES |
| * DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR |
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN |
| * PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER |
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF |
| * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR |
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. |
| * PERFORMANCE OF THIS SOFTWARE. |
|
| */ |
*/ |
| |
#ifdef HAVE_CONFIG_H |
| |
#include "config.h" |
| |
#endif |
| |
|
| #include <assert.h> |
#include <assert.h> |
| #include <ctype.h> |
#include <ctype.h> |
| #include <stdlib.h> |
#include <stdlib.h> |
|
|
| |
|
| #include "libman.h" |
#include "libman.h" |
| |
|
| #define FL_NLINE (1 << 0) |
enum rew { |
| #define FL_TLINE (1 << 1) |
REW_REWIND, |
| |
REW_NOHALT, |
| |
REW_HALT |
| |
}; |
| |
|
| static int man_args(struct man *, int, |
static int blk_close(MACRO_PROT_ARGS); |
| int *, char *, char **); |
static int blk_dotted(MACRO_PROT_ARGS); |
| |
static int blk_exp(MACRO_PROT_ARGS); |
| |
static int blk_imp(MACRO_PROT_ARGS); |
| |
static int in_line_eoln(MACRO_PROT_ARGS); |
| |
|
| static int man_flags[MAN_MAX] = { |
static int rew_scope(enum man_type, |
| 0, /* __ */ |
struct man *, enum mant); |
| 0, /* TH */ |
static enum rew rew_dohalt(enum mant, enum man_type, |
| 0, /* SH */ |
const struct man_node *); |
| 0, /* SS */ |
static enum rew rew_block(enum mant, enum man_type, |
| FL_TLINE, /* TP */ |
const struct man_node *); |
| 0, /* LP */ |
static int rew_warn(struct man *, |
| 0, /* PP */ |
struct man_node *, enum merr); |
| 0, /* P */ |
|
| 0, /* IP */ |
const struct man_macro __man_macros[MAN_MAX] = { |
| 0, /* HP */ |
{ in_line_eoln, MAN_NSCOPED }, /* br */ |
| FL_NLINE, /* SM */ |
{ in_line_eoln, 0 }, /* TH */ |
| FL_NLINE, /* SB */ |
{ blk_imp, MAN_SCOPED }, /* SH */ |
| FL_NLINE, /* BI */ |
{ blk_imp, MAN_SCOPED }, /* SS */ |
| FL_NLINE, /* IB */ |
{ blk_imp, MAN_SCOPED | MAN_FSCOPED }, /* TP */ |
| FL_NLINE, /* BR */ |
{ blk_imp, 0 }, /* LP */ |
| FL_NLINE, /* RB */ |
{ blk_imp, 0 }, /* PP */ |
| FL_NLINE, /* R */ |
{ blk_imp, 0 }, /* P */ |
| FL_NLINE, /* B */ |
{ blk_imp, 0 }, /* IP */ |
| FL_NLINE, /* I */ |
{ blk_imp, 0 }, /* HP */ |
| FL_NLINE, /* IR */ |
{ in_line_eoln, MAN_SCOPED }, /* SM */ |
| FL_NLINE, /* RI */ |
{ in_line_eoln, MAN_SCOPED }, /* SB */ |
| 0, /* br */ |
{ in_line_eoln, 0 }, /* BI */ |
| |
{ in_line_eoln, 0 }, /* IB */ |
| |
{ in_line_eoln, 0 }, /* BR */ |
| |
{ in_line_eoln, 0 }, /* RB */ |
| |
{ in_line_eoln, MAN_SCOPED }, /* R */ |
| |
{ in_line_eoln, MAN_SCOPED }, /* B */ |
| |
{ in_line_eoln, MAN_SCOPED }, /* I */ |
| |
{ in_line_eoln, 0 }, /* IR */ |
| |
{ in_line_eoln, 0 }, /* RI */ |
| |
{ in_line_eoln, MAN_NSCOPED }, /* na */ |
| |
{ in_line_eoln, 0 }, /* i */ |
| |
{ in_line_eoln, MAN_NSCOPED }, /* sp */ |
| |
{ in_line_eoln, 0 }, /* nf */ |
| |
{ in_line_eoln, 0 }, /* fi */ |
| |
{ in_line_eoln, 0 }, /* r */ |
| |
{ blk_close, 0 }, /* RE */ |
| |
{ blk_exp, MAN_EXPLICIT }, /* RS */ |
| |
{ in_line_eoln, 0 }, /* DT */ |
| |
{ in_line_eoln, 0 }, /* UC */ |
| |
{ in_line_eoln, 0 }, /* PD */ |
| |
{ in_line_eoln, MAN_NSCOPED }, /* Sp */ |
| |
{ in_line_eoln, 0 }, /* Vb */ |
| |
{ in_line_eoln, 0 }, /* Ve */ |
| |
{ blk_exp, MAN_EXPLICIT | MAN_NOCLOSE}, /* de */ |
| |
{ blk_exp, MAN_EXPLICIT | MAN_NOCLOSE}, /* dei */ |
| |
{ blk_exp, MAN_EXPLICIT | MAN_NOCLOSE}, /* am */ |
| |
{ blk_exp, MAN_EXPLICIT | MAN_NOCLOSE}, /* ami */ |
| |
{ blk_exp, MAN_EXPLICIT | MAN_NOCLOSE}, /* ig */ |
| |
{ blk_dotted, 0 }, /* . */ |
| }; |
}; |
| |
|
| int |
const struct man_macro * const man_macros = __man_macros; |
| man_macro(struct man *man, int tok, int line, |
|
| int ppos, int *pos, char *buf) |
|
| |
/* |
| |
* Warn when "n" is an explicit non-roff macro. |
| |
*/ |
| |
static int |
| |
rew_warn(struct man *m, struct man_node *n, enum merr er) |
| { |
{ |
| int w, la; |
|
| char *p; |
|
| struct man_node *n; |
|
| |
|
| if ( ! man_elem_alloc(man, line, ppos, tok)) |
if (er == WERRMAX || MAN_BLOCK != n->type) |
| return(0); |
return(1); |
| n = man->last; |
if (MAN_VALID & n->flags) |
| man->next = MAN_NEXT_CHILD; |
return(1); |
| |
if ( ! (MAN_EXPLICIT & man_macros[n->tok].flags)) |
| |
return(1); |
| |
if (MAN_NOCLOSE & man_macros[n->tok].flags) |
| |
return(1); |
| |
return(man_nwarn(m, n, er)); |
| |
} |
| |
|
| for (;;) { |
|
| la = *pos; |
|
| w = man_args(man, line, pos, buf, &p); |
|
| |
|
| if (-1 == w) |
/* |
| return(0); |
* Rewind scope. If a code "er" != WERRMAX has been provided, it will |
| if (0 == w) |
* be used if an explicit block scope is being closed out. |
| break; |
*/ |
| |
int |
| |
man_unscope(struct man *m, const struct man_node *n, enum merr er) |
| |
{ |
| |
|
| if ( ! man_word_alloc(man, line, la, p)) |
assert(n); |
| |
|
| |
/* LINTED */ |
| |
while (m->last != n) { |
| |
if ( ! rew_warn(m, m->last, er)) |
| return(0); |
return(0); |
| man->next = MAN_NEXT_SIBLING; |
if ( ! man_valid_post(m)) |
| |
return(0); |
| |
if ( ! man_action_post(m)) |
| |
return(0); |
| |
m->last = m->last->parent; |
| |
assert(m->last); |
| } |
} |
| |
|
| if (n == man->last && (FL_NLINE & man_flags[tok])) { |
if ( ! rew_warn(m, m->last, er)) |
| if (MAN_NLINE & man->flags) |
return(0); |
| return(man_verr(man, line, ppos, |
if ( ! man_valid_post(m)) |
| "next-line scope already open")); |
return(0); |
| man->flags |= MAN_NLINE; |
if ( ! man_action_post(m)) |
| return(1); |
return(0); |
| |
|
| |
m->next = MAN_ROOT == m->last->type ? |
| |
MAN_NEXT_CHILD : MAN_NEXT_SIBLING; |
| |
|
| |
return(1); |
| |
} |
| |
|
| |
|
| |
static enum rew |
| |
rew_block(enum mant ntok, enum man_type type, const struct man_node *n) |
| |
{ |
| |
|
| |
if (MAN_BLOCK == type && ntok == n->parent->tok && |
| |
MAN_BODY == n->parent->type) |
| |
return(REW_REWIND); |
| |
return(ntok == n->tok ? REW_HALT : REW_NOHALT); |
| |
} |
| |
|
| |
|
| |
/* |
| |
* There are three scope levels: scoped to the root (all), scoped to the |
| |
* section (all less sections), and scoped to subsections (all less |
| |
* sections and subsections). |
| |
*/ |
| |
static enum rew |
| |
rew_dohalt(enum mant tok, enum man_type type, const struct man_node *n) |
| |
{ |
| |
enum rew c; |
| |
|
| |
/* We cannot progress beyond the root ever. */ |
| |
if (MAN_ROOT == n->type) |
| |
return(REW_HALT); |
| |
|
| |
assert(n->parent); |
| |
|
| |
/* Normal nodes shouldn't go to the level of the root. */ |
| |
if (MAN_ROOT == n->parent->type) |
| |
return(REW_REWIND); |
| |
|
| |
/* Already-validated nodes should be closed out. */ |
| |
if (MAN_VALID & n->flags) |
| |
return(REW_NOHALT); |
| |
|
| |
/* First: rewind to ourselves. */ |
| |
if (type == n->type && tok == n->tok) |
| |
return(REW_REWIND); |
| |
|
| |
/* |
| |
* If we're a roff macro, then we can close out anything that |
| |
* stands between us and our parent context. |
| |
*/ |
| |
if (MAN_NOCLOSE & man_macros[tok].flags) |
| |
return(REW_NOHALT); |
| |
|
| |
/* |
| |
* Don't clobber roff macros: this is a bit complicated. If the |
| |
* current macro is a roff macro, halt immediately and don't |
| |
* rewind. If it's not, and the parent is, then close out the |
| |
* current scope and halt at the parent. |
| |
*/ |
| |
if (MAN_NOCLOSE & man_macros[n->tok].flags) |
| |
return(REW_HALT); |
| |
if (MAN_NOCLOSE & man_macros[n->parent->tok].flags) |
| |
return(REW_REWIND); |
| |
|
| |
/* |
| |
* Next follow the implicit scope-smashings as defined by man.7: |
| |
* section, sub-section, etc. |
| |
*/ |
| |
|
| |
switch (tok) { |
| |
case (MAN_SH): |
| |
break; |
| |
case (MAN_SS): |
| |
/* Rewind to a section, if a block. */ |
| |
if (REW_NOHALT != (c = rew_block(MAN_SH, type, n))) |
| |
return(c); |
| |
break; |
| |
case (MAN_RS): |
| |
/* Rewind to a subsection, if a block. */ |
| |
if (REW_NOHALT != (c = rew_block(MAN_SS, type, n))) |
| |
return(c); |
| |
/* Rewind to a section, if a block. */ |
| |
if (REW_NOHALT != (c = rew_block(MAN_SH, type, n))) |
| |
return(c); |
| |
break; |
| |
default: |
| |
/* Rewind to an offsetter, if a block. */ |
| |
if (REW_NOHALT != (c = rew_block(MAN_RS, type, n))) |
| |
return(c); |
| |
/* Rewind to a subsection, if a block. */ |
| |
if (REW_NOHALT != (c = rew_block(MAN_SS, type, n))) |
| |
return(c); |
| |
/* Rewind to a section, if a block. */ |
| |
if (REW_NOHALT != (c = rew_block(MAN_SH, type, n))) |
| |
return(c); |
| |
break; |
| } |
} |
| |
|
| if (FL_TLINE & man_flags[tok]) { |
return(REW_NOHALT); |
| if (MAN_NLINE & man->flags) |
} |
| return(man_verr(man, line, ppos, |
|
| "next-line scope already open")); |
|
| man->flags |= MAN_NLINE; |
/* |
| return(1); |
* Rewinding entails ascending the parse tree until a coherent point, |
| |
* for example, the `SH' macro will close out any intervening `SS' |
| |
* scopes. When a scope is closed, it must be validated and actioned. |
| |
*/ |
| |
static int |
| |
rew_scope(enum man_type type, struct man *m, enum mant tok) |
| |
{ |
| |
struct man_node *n; |
| |
enum rew c; |
| |
|
| |
/* LINTED */ |
| |
for (n = m->last; n; n = n->parent) { |
| |
/* |
| |
* Whether we should stop immediately (REW_HALT), stop |
| |
* and rewind until this point (REW_REWIND), or keep |
| |
* rewinding (REW_NOHALT). |
| |
*/ |
| |
c = rew_dohalt(tok, type, n); |
| |
if (REW_HALT == c) |
| |
return(1); |
| |
if (REW_REWIND == c) |
| |
break; |
| } |
} |
| |
|
| /* |
/* |
| * Note that when TH is pruned, we'll be back at the root, so |
* Rewind until the current point. Warn if we're a roff |
| * make sure that we don't clobber as its sibling. |
* instruction that's mowing over explicit scopes. |
| */ |
*/ |
| |
assert(n); |
| |
if (MAN_NOCLOSE & man_macros[tok].flags) |
| |
return(man_unscope(m, n, WROFFSCOPE)); |
| |
|
| for ( ; man->last; man->last = man->last->parent) { |
return(man_unscope(m, n, WERRMAX)); |
| if (man->last == n) |
} |
| |
|
| |
|
| |
/* |
| |
* Closure for dotted macros (de, dei, am, ami, ign). This must handle |
| |
* any of these as the parent node, so it needs special handling. |
| |
* Beyond this, it's the same as blk_close(). |
| |
*/ |
| |
/* ARGSUSED */ |
| |
int |
| |
blk_dotted(MACRO_PROT_ARGS) |
| |
{ |
| |
enum mant ntok; |
| |
struct man_node *nn; |
| |
|
| |
/* Check for any of the following parents... */ |
| |
|
| |
for (nn = m->last->parent; nn; nn = nn->parent) |
| |
if (nn->tok == MAN_de || nn->tok == MAN_dei || |
| |
nn->tok == MAN_am || |
| |
nn->tok == MAN_ami || |
| |
nn->tok == MAN_ig) { |
| |
ntok = nn->tok; |
| break; |
break; |
| if (man->last->type == MAN_ROOT) |
} |
| break; |
|
| if ( ! man_valid_post(man)) |
if (NULL == nn) { |
| |
if ( ! man_pwarn(m, line, ppos, WNOSCOPE)) |
| return(0); |
return(0); |
| if ( ! man_action_post(man)) |
return(1); |
| return(0); |
|
| } |
} |
| |
|
| assert(man->last); |
if ( ! rew_scope(MAN_BODY, m, ntok)) |
| |
return(0); |
| |
if ( ! rew_scope(MAN_BLOCK, m, ntok)) |
| |
return(0); |
| |
|
| /* |
/* |
| * Same here regarding whether we're back at the root. |
* XXX: manually adjust our next-line status. roff macros are, |
| |
* for the moment, ignored, so we don't want to close out bodies |
| |
* and so on. |
| */ |
*/ |
| |
|
| if (man->last->type != MAN_ROOT && ! man_valid_post(man)) |
switch (m->last->type) { |
| |
case (MAN_BODY): |
| |
m->next = MAN_NEXT_CHILD; |
| |
break; |
| |
default: |
| |
break; |
| |
} |
| |
|
| |
return(1); |
| |
} |
| |
|
| |
|
| |
/* |
| |
* Close out a generic explicit macro. |
| |
*/ |
| |
/* ARGSUSED */ |
| |
int |
| |
blk_close(MACRO_PROT_ARGS) |
| |
{ |
| |
enum mant ntok; |
| |
const struct man_node *nn; |
| |
|
| |
switch (tok) { |
| |
case (MAN_RE): |
| |
ntok = MAN_RS; |
| |
break; |
| |
default: |
| |
abort(); |
| |
/* NOTREACHED */ |
| |
} |
| |
|
| |
for (nn = m->last->parent; nn; nn = nn->parent) |
| |
if (ntok == nn->tok) |
| |
break; |
| |
|
| |
if (NULL == nn) |
| |
if ( ! man_pwarn(m, line, ppos, WNOSCOPE)) |
| |
return(0); |
| |
|
| |
if ( ! rew_scope(MAN_BODY, m, ntok)) |
| return(0); |
return(0); |
| if (man->last->type != MAN_ROOT && ! man_action_post(man)) |
if ( ! rew_scope(MAN_BLOCK, m, ntok)) |
| return(0); |
return(0); |
| if (man->last->type != MAN_ROOT) |
|
| man->next = MAN_NEXT_SIBLING; |
|
| |
|
| return(1); |
return(1); |
| } |
} |
| |
|
| |
|
| int |
int |
| man_macroend(struct man *m) |
blk_exp(MACRO_PROT_ARGS) |
| { |
{ |
| |
int w, la; |
| |
char *p; |
| |
|
| for ( ; m->last && m->last != m->first; |
/* |
| m->last = m->last->parent) { |
* Close out prior scopes. "Regular" explicit macros cannot be |
| if ( ! man_valid_post(m)) |
* nested, but we allow roff macros to be placed just about |
| |
* anywhere. |
| |
*/ |
| |
|
| |
if ( ! (MAN_NOCLOSE & man_macros[tok].flags)) { |
| |
if ( ! rew_scope(MAN_BODY, m, tok)) |
| return(0); |
return(0); |
| if ( ! man_action_post(m)) |
if ( ! rew_scope(MAN_BLOCK, m, tok)) |
| return(0); |
return(0); |
| } |
} |
| assert(m->last == m->first); |
|
| |
|
| if ( ! man_valid_post(m)) |
if ( ! man_block_alloc(m, line, ppos, tok)) |
| return(0); |
return(0); |
| if ( ! man_action_post(m)) |
if ( ! man_head_alloc(m, line, ppos, tok)) |
| return(0); |
return(0); |
| |
|
| return(1); |
for (;;) { |
| |
la = *pos; |
| |
w = man_args(m, line, pos, buf, &p); |
| |
|
| |
if (-1 == w) |
| |
return(0); |
| |
if (0 == w) |
| |
break; |
| |
|
| |
if ( ! man_word_alloc(m, line, la, p)) |
| |
return(0); |
| |
} |
| |
|
| |
assert(m); |
| |
assert(tok != MAN_MAX); |
| |
|
| |
if ( ! rew_scope(MAN_HEAD, m, tok)) |
| |
return(0); |
| |
return(man_body_alloc(m, line, ppos, tok)); |
| } |
} |
| |
|
| |
|
| /* ARGSUSED */ |
|
| static int |
/* |
| man_args(struct man *m, int line, |
* Parse an implicit-block macro. These contain a MAN_HEAD and a |
| int *pos, char *buf, char **v) |
* MAN_BODY contained within a MAN_BLOCK. Rules for closing out other |
| |
* scopes, such as `SH' closing out an `SS', are defined in the rew |
| |
* routines. |
| |
*/ |
| |
int |
| |
blk_imp(MACRO_PROT_ARGS) |
| { |
{ |
| |
int w, la; |
| |
char *p; |
| |
struct man_node *n; |
| |
|
| if (0 == buf[*pos]) |
/* Close out prior scopes. */ |
| |
|
| |
if ( ! rew_scope(MAN_BODY, m, tok)) |
| return(0); |
return(0); |
| |
if ( ! rew_scope(MAN_BLOCK, m, tok)) |
| |
return(0); |
| |
|
| /* First parse non-quoted strings. */ |
/* Allocate new block & head scope. */ |
| |
|
| if ('\"' != buf[*pos]) { |
if ( ! man_block_alloc(m, line, ppos, tok)) |
| *v = &buf[*pos]; |
return(0); |
| |
if ( ! man_head_alloc(m, line, ppos, tok)) |
| |
return(0); |
| |
|
| while (buf[*pos]) { |
n = m->last; |
| if (' ' == buf[*pos]) |
|
| if ('\\' != buf[*pos - 1]) |
|
| break; |
|
| (*pos)++; |
|
| } |
|
| |
|
| if (0 == buf[*pos]) |
/* Add line arguments. */ |
| return(1); |
|
| |
|
| buf[(*pos)++] = 0; |
for (;;) { |
| |
la = *pos; |
| |
w = man_args(m, line, pos, buf, &p); |
| |
|
| if (0 == buf[*pos]) |
if (-1 == w) |
| return(1); |
return(0); |
| |
if (0 == w) |
| |
break; |
| |
|
| while (buf[*pos] && ' ' == buf[*pos]) |
if ( ! man_word_alloc(m, line, la, p)) |
| (*pos)++; |
return(0); |
| |
} |
| |
|
| if (buf[*pos]) |
/* Close out head and open body (unless MAN_SCOPE). */ |
| |
|
| |
if (MAN_SCOPED & man_macros[tok].flags) { |
| |
/* If we're forcing scope (`TP'), keep it open. */ |
| |
if (MAN_FSCOPED & man_macros[tok].flags) { |
| |
m->flags |= MAN_BLINE; |
| return(1); |
return(1); |
| |
} else if (n == m->last) { |
| |
m->flags |= MAN_BLINE; |
| |
return(1); |
| |
} |
| |
} |
| |
|
| if ( ! man_vwarn(m, line, *pos, "trailing spaces")) |
if ( ! rew_scope(MAN_HEAD, m, tok)) |
| return(-1); |
return(0); |
| |
return(man_body_alloc(m, line, ppos, tok)); |
| |
} |
| |
|
| return(1); |
|
| |
int |
| |
in_line_eoln(MACRO_PROT_ARGS) |
| |
{ |
| |
int w, la; |
| |
char *p; |
| |
struct man_node *n; |
| |
|
| |
if ( ! man_elem_alloc(m, line, ppos, tok)) |
| |
return(0); |
| |
|
| |
n = m->last; |
| |
|
| |
for (;;) { |
| |
la = *pos; |
| |
w = man_args(m, line, pos, buf, &p); |
| |
|
| |
if (-1 == w) |
| |
return(0); |
| |
if (0 == w) |
| |
break; |
| |
if ( ! man_word_alloc(m, line, la, p)) |
| |
return(0); |
| } |
} |
| |
|
| /* |
/* |
| * If we're a quoted string (and quoted strings are allowed), |
* If no arguments are specified and this is MAN_SCOPED (i.e., |
| * then parse ahead to the next quote. If none's found, it's an |
* next-line scoped), then set our mode to indicate that we're |
| * error. After, parse to the next word. |
* waiting for terms to load into our context. |
| */ |
*/ |
| |
|
| *v = &buf[++(*pos)]; |
if (n == m->last && MAN_SCOPED & man_macros[tok].flags) { |
| |
assert( ! (MAN_NSCOPED & man_macros[tok].flags)); |
| |
m->flags |= MAN_ELINE; |
| |
return(1); |
| |
} |
| |
|
| while (buf[*pos] && '\"' != buf[*pos]) |
/* Set ignorable context, if applicable. */ |
| (*pos)++; |
|
| |
|
| if (0 == buf[*pos]) { |
if (MAN_NSCOPED & man_macros[tok].flags) { |
| if ( ! man_vwarn(m, line, *pos, "unterminated quote")) |
assert( ! (MAN_SCOPED & man_macros[tok].flags)); |
| return(-1); |
m->flags |= MAN_ILINE; |
| return(1); |
|
| } |
} |
| |
|
| |
/* |
| |
* Rewind our element scope. Note that when TH is pruned, we'll |
| |
* be back at the root, so make sure that we don't clobber as |
| |
* its sibling. |
| |
*/ |
| |
|
| buf[(*pos)++] = 0; |
for ( ; m->last; m->last = m->last->parent) { |
| if (0 == buf[*pos]) |
if (m->last == n) |
| return(1); |
break; |
| |
if (m->last->type == MAN_ROOT) |
| |
break; |
| |
if ( ! man_valid_post(m)) |
| |
return(0); |
| |
if ( ! man_action_post(m)) |
| |
return(0); |
| |
} |
| |
|
| while (buf[*pos] && ' ' == buf[*pos]) |
assert(m->last); |
| (*pos)++; |
|
| |
|
| if (buf[*pos]) |
/* |
| return(1); |
* Same here regarding whether we're back at the root. |
| |
*/ |
| |
|
| if ( ! man_vwarn(m, line, *pos, "trailing spaces")) |
if (m->last->type != MAN_ROOT && ! man_valid_post(m)) |
| return(-1); |
return(0); |
| |
if (m->last->type != MAN_ROOT && ! man_action_post(m)) |
| |
return(0); |
| |
|
| |
m->next = MAN_ROOT == m->last->type ? |
| |
MAN_NEXT_CHILD : MAN_NEXT_SIBLING; |
| |
|
| return(1); |
return(1); |
| } |
} |
| |
|
| |
|
| |
int |
| |
man_macroend(struct man *m) |
| |
{ |
| |
|
| |
return(man_unscope(m, m->first, WEXITSCOPE)); |
| |
} |
| |
|
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