/* $Id$ */ /* * Copyright (c) 2008, 2009, 2010, 2011 Kristaps Dzonsons * Copyright (c) 2012, 2013, 2014, 2015 Ingo Schwarze * Copyright (c) 2013 Franco Fichtner * * 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 AUTHORS DISCLAIM ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHORS 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 "config.h" #include #include #include #include #include #include "mandoc.h" #include "roff.h" #include "man.h" #include "libmandoc.h" #include "libman.h" enum rew { REW_REWIND, REW_NOHALT, REW_HALT }; static void blk_close(MACRO_PROT_ARGS); static void blk_exp(MACRO_PROT_ARGS); static void blk_imp(MACRO_PROT_ARGS); static void in_line_eoln(MACRO_PROT_ARGS); static int man_args(struct man *, int, int *, char *, char **); static void rew_scope(enum roff_type, struct man *, int); static enum rew rew_dohalt(int, enum roff_type, const struct roff_node *); static enum rew rew_block(int, enum roff_type, const struct roff_node *); const struct man_macro __man_macros[MAN_MAX] = { { in_line_eoln, MAN_NSCOPED }, /* br */ { in_line_eoln, MAN_BSCOPE }, /* TH */ { blk_imp, MAN_BSCOPE | MAN_SCOPED }, /* SH */ { blk_imp, MAN_BSCOPE | MAN_SCOPED }, /* SS */ { blk_imp, MAN_BSCOPE | MAN_SCOPED }, /* TP */ { blk_imp, MAN_BSCOPE }, /* LP */ { blk_imp, MAN_BSCOPE }, /* PP */ { blk_imp, MAN_BSCOPE }, /* P */ { blk_imp, MAN_BSCOPE }, /* IP */ { blk_imp, MAN_BSCOPE }, /* HP */ { in_line_eoln, MAN_SCOPED | MAN_JOIN }, /* SM */ { in_line_eoln, MAN_SCOPED | MAN_JOIN }, /* SB */ { 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 | MAN_JOIN }, /* R */ { in_line_eoln, MAN_SCOPED | MAN_JOIN }, /* B */ { in_line_eoln, MAN_SCOPED | MAN_JOIN }, /* I */ { in_line_eoln, 0 }, /* IR */ { in_line_eoln, 0 }, /* RI */ { in_line_eoln, MAN_NSCOPED }, /* sp */ { in_line_eoln, MAN_BSCOPE }, /* nf */ { in_line_eoln, MAN_BSCOPE }, /* fi */ { blk_close, MAN_BSCOPE }, /* RE */ { blk_exp, MAN_BSCOPE }, /* RS */ { in_line_eoln, 0 }, /* DT */ { in_line_eoln, 0 }, /* UC */ { in_line_eoln, MAN_NSCOPED }, /* PD */ { in_line_eoln, 0 }, /* AT */ { in_line_eoln, 0 }, /* in */ { in_line_eoln, 0 }, /* ft */ { in_line_eoln, 0 }, /* OP */ { in_line_eoln, MAN_BSCOPE }, /* EX */ { in_line_eoln, MAN_BSCOPE }, /* EE */ { blk_exp, MAN_BSCOPE }, /* UR */ { blk_close, MAN_BSCOPE }, /* UE */ { in_line_eoln, 0 }, /* ll */ }; const struct man_macro * const man_macros = __man_macros; void man_unscope(struct man *man, const struct roff_node *to) { struct roff_node *n; to = to->parent; n = man->last; while (n != to) { /* Reached the end of the document? */ if (to == NULL && ! (n->flags & MAN_VALID)) { if (man->flags & (MAN_BLINE | MAN_ELINE) && man_macros[n->tok].flags & MAN_SCOPED) { mandoc_vmsg(MANDOCERR_BLK_LINE, man->parse, n->line, n->pos, "EOF breaks %s", man_macronames[n->tok]); if (man->flags & MAN_ELINE) man->flags &= ~MAN_ELINE; else { assert(n->type == ROFFT_HEAD); n = n->parent; man->flags &= ~MAN_BLINE; } man->last = n; n = n->parent; man_node_delete(man, man->last); continue; } if (n->type == ROFFT_BLOCK && man_macros[n->tok].fp == blk_exp) mandoc_msg(MANDOCERR_BLK_NOEND, man->parse, n->line, n->pos, man_macronames[n->tok]); } /* * We might delete the man->last node * in the post-validation phase. * Save a pointer to the parent such that * we know where to continue the iteration. */ man->last = n; n = n->parent; man_valid_post(man); } /* * If we ended up at the parent of the node we were * supposed to rewind to, that means the target node * got deleted, so add the next node we parse as a child * of the parent instead of as a sibling of the target. */ man->next = (man->last == to) ? MAN_NEXT_CHILD : MAN_NEXT_SIBLING; } static enum rew rew_block(int ntok, enum roff_type type, const struct roff_node *n) { if (type == ROFFT_BLOCK && n->parent->tok == ntok && n->parent->type == ROFFT_BODY) 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(int tok, enum roff_type type, const struct roff_node *n) { enum rew c; /* We cannot progress beyond the root ever. */ if (n->type == ROFFT_ROOT) return(REW_HALT); assert(n->parent); /* Normal nodes shouldn't go to the level of the root. */ if (n->parent->type == ROFFT_ROOT) 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) { if (man_macros[n->tok].fp == blk_exp) return(REW_HALT); else 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: /* Preserve empty paragraphs before RS. */ if (0 == n->nchild && (MAN_P == n->tok || MAN_PP == n->tok || MAN_LP == n->tok)) return(REW_HALT); /* 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; } return(REW_NOHALT); } /* * 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 void rew_scope(enum roff_type type, struct man *man, int tok) { struct roff_node *n; enum rew c; for (n = man->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; if (REW_REWIND == c) break; } /* * Rewind until the current point. Warn if we're a roff * instruction that's mowing over explicit scopes. */ man_unscope(man, n); } /* * Close out a generic explicit macro. */ void blk_close(MACRO_PROT_ARGS) { int ntok; const struct roff_node *nn; char *p; int nrew, target; nrew = 1; switch (tok) { case MAN_RE: ntok = MAN_RS; if ( ! man_args(man, line, pos, buf, &p)) break; for (nn = man->last->parent; nn; nn = nn->parent) if (nn->tok == ntok && nn->type == ROFFT_BLOCK) nrew++; target = strtol(p, &p, 10); if (*p != '\0') mandoc_vmsg(MANDOCERR_ARG_EXCESS, man->parse, line, p - buf, "RE ... %s", p); if (target == 0) target = 1; nrew -= target; if (nrew < 1) { mandoc_vmsg(MANDOCERR_RE_NOTOPEN, man->parse, line, ppos, "RE %d", target); return; } break; case MAN_UE: ntok = MAN_UR; break; default: abort(); /* NOTREACHED */ } for (nn = man->last->parent; nn; nn = nn->parent) if (nn->tok == ntok && nn->type == ROFFT_BLOCK && ! --nrew) break; if (nn == NULL) { mandoc_msg(MANDOCERR_BLK_NOTOPEN, man->parse, line, ppos, man_macronames[tok]); rew_scope(ROFFT_BLOCK, man, MAN_PP); } else { line = man->last->line; ppos = man->last->pos; ntok = man->last->tok; man_unscope(man, nn); /* Move a trailing paragraph behind the block. */ if (ntok == MAN_LP || ntok == MAN_PP || ntok == MAN_P) { *pos = strlen(buf); blk_imp(man, ntok, line, ppos, pos, buf); } } } void blk_exp(MACRO_PROT_ARGS) { struct roff_node *head; char *p; int la; rew_scope(ROFFT_BLOCK, man, tok); man_block_alloc(man, line, ppos, tok); man_head_alloc(man, line, ppos, tok); head = man->last; la = *pos; if (man_args(man, line, pos, buf, &p)) man_word_alloc(man, line, la, p); if (buf[*pos] != '\0') mandoc_vmsg(MANDOCERR_ARG_EXCESS, man->parse, line, *pos, "%s ... %s", man_macronames[tok], buf + *pos); man_unscope(man, head); man_body_alloc(man, line, ppos, tok); } /* * Parse an implicit-block macro. These contain a ROFFT_HEAD and a * ROFFT_BODY contained within a ROFFT_BLOCK. Rules for closing out other * scopes, such as `SH' closing out an `SS', are defined in the rew * routines. */ void blk_imp(MACRO_PROT_ARGS) { int la; char *p; struct roff_node *n; rew_scope(ROFFT_BODY, man, tok); rew_scope(ROFFT_BLOCK, man, tok); man_block_alloc(man, line, ppos, tok); man_head_alloc(man, line, ppos, tok); n = man->last; /* Add line arguments. */ for (;;) { la = *pos; if ( ! man_args(man, line, pos, buf, &p)) break; man_word_alloc(man, line, la, p); } /* * For macros having optional next-line scope, * keep the head open if there were no arguments. * For `TP', always keep the head open. */ if (man_macros[tok].flags & MAN_SCOPED && (tok == MAN_TP || n == man->last)) { man->flags |= MAN_BLINE; return; } /* Close out the head and open the body. */ rew_scope(ROFFT_HEAD, man, tok); man_body_alloc(man, line, ppos, tok); } void in_line_eoln(MACRO_PROT_ARGS) { int la; char *p; struct roff_node *n; man_elem_alloc(man, line, ppos, tok); n = man->last; for (;;) { if (buf[*pos] != '\0' && (tok == MAN_br || tok == MAN_fi || tok == MAN_nf)) { mandoc_vmsg(MANDOCERR_ARG_SKIP, man->parse, line, *pos, "%s %s", man_macronames[tok], buf + *pos); break; } if (buf[*pos] != '\0' && man->last != n && (tok == MAN_PD || tok == MAN_ft || tok == MAN_sp)) { mandoc_vmsg(MANDOCERR_ARG_EXCESS, man->parse, line, *pos, "%s ... %s", man_macronames[tok], buf + *pos); break; } la = *pos; if ( ! man_args(man, line, pos, buf, &p)) break; if (man_macros[tok].flags & MAN_JOIN && man->last->type == ROFFT_TEXT) man_word_append(man, p); else man_word_alloc(man, line, la, p); } /* * Append MAN_EOS in case the last snipped argument * ends with a dot, e.g. `.IR syslog (3).' */ if (n != man->last && mandoc_eos(man->last->string, strlen(man->last->string))) man->last->flags |= MAN_EOS; /* * If no arguments are specified and this is MAN_SCOPED (i.e., * next-line scoped), then set our mode to indicate that we're * waiting for terms to load into our context. */ if (n == man->last && man_macros[tok].flags & MAN_SCOPED) { assert( ! (man_macros[tok].flags & MAN_NSCOPED)); man->flags |= MAN_ELINE; return; } assert(man->last->type != ROFFT_ROOT); man->next = MAN_NEXT_SIBLING; /* * 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. */ for ( ; man->last; man->last = man->last->parent) { if (man->last == n) break; if (man->last->type == ROFFT_ROOT) break; man_valid_post(man); } assert(man->last); /* * Same here regarding whether we're back at the root. */ if (man->last->type != ROFFT_ROOT) man_valid_post(man); } void man_macroend(struct man *man) { man_unscope(man, man->first); } static int man_args(struct man *man, int line, int *pos, char *buf, char **v) { char *start; assert(*pos); *v = start = buf + *pos; assert(' ' != *start); if ('\0' == *start) return(0); *v = mandoc_getarg(man->parse, v, line, pos); return(1); }