/* $Id$ */ /* * Copyright (c) 2010, 2011, 2012 Kristaps Dzonsons * Copyright (c) 2010-2014 Ingo Schwarze * * 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. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include "mandoc.h" #include "mandoc_aux.h" #include "libroff.h" #include "libmandoc.h" /* Maximum number of nested if-else conditionals. */ #define RSTACK_MAX 128 /* Maximum number of string expansions per line, to break infinite loops. */ #define EXPAND_LIMIT 1000 enum rofft { ROFF_ad, ROFF_am, ROFF_ami, ROFF_am1, ROFF_as, ROFF_cc, ROFF_ce, ROFF_de, ROFF_dei, ROFF_de1, ROFF_ds, ROFF_el, ROFF_fam, ROFF_hw, ROFF_hy, ROFF_ie, ROFF_if, ROFF_ig, ROFF_it, ROFF_ne, ROFF_nh, ROFF_nr, ROFF_ns, ROFF_ps, ROFF_rm, ROFF_rr, ROFF_so, ROFF_ta, ROFF_tr, ROFF_Dd, ROFF_TH, ROFF_TS, ROFF_TE, ROFF_T_, ROFF_EQ, ROFF_EN, ROFF_cblock, ROFF_USERDEF, ROFF_MAX }; /* * An incredibly-simple string buffer. */ struct roffstr { char *p; /* nil-terminated buffer */ size_t sz; /* saved strlen(p) */ }; /* * A key-value roffstr pair as part of a singly-linked list. */ struct roffkv { struct roffstr key; struct roffstr val; struct roffkv *next; /* next in list */ }; /* * A single number register as part of a singly-linked list. */ struct roffreg { struct roffstr key; int val; struct roffreg *next; }; struct roff { struct mparse *parse; /* parse point */ int options; /* parse options */ struct roffnode *last; /* leaf of stack */ int rstack[RSTACK_MAX]; /* stack of !`ie' rules */ char control; /* control character */ int rstackpos; /* position in rstack */ struct roffreg *regtab; /* number registers */ struct roffkv *strtab; /* user-defined strings & macros */ struct roffkv *xmbtab; /* multi-byte trans table (`tr') */ struct roffstr *xtab; /* single-byte trans table (`tr') */ const char *current_string; /* value of last called user macro */ struct tbl_node *first_tbl; /* first table parsed */ struct tbl_node *last_tbl; /* last table parsed */ struct tbl_node *tbl; /* current table being parsed */ struct eqn_node *last_eqn; /* last equation parsed */ struct eqn_node *first_eqn; /* first equation parsed */ struct eqn_node *eqn; /* current equation being parsed */ }; struct roffnode { enum rofft tok; /* type of node */ struct roffnode *parent; /* up one in stack */ int line; /* parse line */ int col; /* parse col */ char *name; /* node name, e.g. macro name */ char *end; /* end-rules: custom token */ int endspan; /* end-rules: next-line or infty */ int rule; /* current evaluation rule */ }; #define ROFF_ARGS struct roff *r, /* parse ctx */ \ enum rofft tok, /* tok of macro */ \ char **bufp, /* input buffer */ \ size_t *szp, /* size of input buffer */ \ int ln, /* parse line */ \ int ppos, /* original pos in buffer */ \ int pos, /* current pos in buffer */ \ int *offs /* reset offset of buffer data */ typedef enum rofferr (*roffproc)(ROFF_ARGS); struct roffmac { const char *name; /* macro name */ roffproc proc; /* process new macro */ roffproc text; /* process as child text of macro */ roffproc sub; /* process as child of macro */ int flags; #define ROFFMAC_STRUCT (1 << 0) /* always interpret */ struct roffmac *next; }; struct predef { const char *name; /* predefined input name */ const char *str; /* replacement symbol */ }; #define PREDEF(__name, __str) \ { (__name), (__str) }, static enum rofft roffhash_find(const char *, size_t); static void roffhash_init(void); static void roffnode_cleanscope(struct roff *); static void roffnode_pop(struct roff *); static void roffnode_push(struct roff *, enum rofft, const char *, int, int); static enum rofferr roff_block(ROFF_ARGS); static enum rofferr roff_block_text(ROFF_ARGS); static enum rofferr roff_block_sub(ROFF_ARGS); static enum rofferr roff_cblock(ROFF_ARGS); static enum rofferr roff_cc(ROFF_ARGS); static void roff_ccond(struct roff *, int, int); static enum rofferr roff_cond(ROFF_ARGS); static enum rofferr roff_cond_text(ROFF_ARGS); static enum rofferr roff_cond_sub(ROFF_ARGS); static enum rofferr roff_ds(ROFF_ARGS); static int roff_evalcond(const char *, int *); static int roff_evalnum(const char *, int *, int *, int); static int roff_evalpar(const char *, int *, int *); static int roff_evalstrcond(const char *, int *); static void roff_free1(struct roff *); static void roff_freereg(struct roffreg *); static void roff_freestr(struct roffkv *); static size_t roff_getname(struct roff *, char **, int, int); static int roff_getnum(const char *, int *, int *); static int roff_getop(const char *, int *, char *); static int roff_getregn(const struct roff *, const char *, size_t); static int roff_getregro(const char *name); static const char *roff_getstrn(const struct roff *, const char *, size_t); static enum rofferr roff_it(ROFF_ARGS); static enum rofferr roff_line_ignore(ROFF_ARGS); static enum rofferr roff_nr(ROFF_ARGS); static void roff_openeqn(struct roff *, const char *, int, int, const char *); static enum rofft roff_parse(struct roff *, char *, int *, int, int); static enum rofferr roff_parsetext(char **, size_t *, int, int *); static enum rofferr roff_res(struct roff *, char **, size_t *, int, int); static enum rofferr roff_rm(ROFF_ARGS); static enum rofferr roff_rr(ROFF_ARGS); static void roff_setstr(struct roff *, const char *, const char *, int); static void roff_setstrn(struct roffkv **, const char *, size_t, const char *, size_t, int); static enum rofferr roff_so(ROFF_ARGS); static enum rofferr roff_tr(ROFF_ARGS); static enum rofferr roff_Dd(ROFF_ARGS); static enum rofferr roff_TH(ROFF_ARGS); static enum rofferr roff_TE(ROFF_ARGS); static enum rofferr roff_TS(ROFF_ARGS); static enum rofferr roff_EQ(ROFF_ARGS); static enum rofferr roff_EN(ROFF_ARGS); static enum rofferr roff_T_(ROFF_ARGS); static enum rofferr roff_userdef(ROFF_ARGS); /* See roffhash_find() */ #define ASCII_HI 126 #define ASCII_LO 33 #define HASHWIDTH (ASCII_HI - ASCII_LO + 1) static struct roffmac *hash[HASHWIDTH]; static struct roffmac roffs[ROFF_MAX] = { { "ad", roff_line_ignore, NULL, NULL, 0, NULL }, { "am", roff_block, roff_block_text, roff_block_sub, 0, NULL }, { "ami", roff_block, roff_block_text, roff_block_sub, 0, NULL }, { "am1", roff_block, roff_block_text, roff_block_sub, 0, NULL }, { "as", roff_ds, NULL, NULL, 0, NULL }, { "cc", roff_cc, NULL, NULL, 0, NULL }, { "ce", roff_line_ignore, NULL, NULL, 0, NULL }, { "de", roff_block, roff_block_text, roff_block_sub, 0, NULL }, { "dei", roff_block, roff_block_text, roff_block_sub, 0, NULL }, { "de1", roff_block, roff_block_text, roff_block_sub, 0, NULL }, { "ds", roff_ds, NULL, NULL, 0, NULL }, { "el", roff_cond, roff_cond_text, roff_cond_sub, ROFFMAC_STRUCT, NULL }, { "fam", roff_line_ignore, NULL, NULL, 0, NULL }, { "hw", roff_line_ignore, NULL, NULL, 0, NULL }, { "hy", roff_line_ignore, NULL, NULL, 0, NULL }, { "ie", roff_cond, roff_cond_text, roff_cond_sub, ROFFMAC_STRUCT, NULL }, { "if", roff_cond, roff_cond_text, roff_cond_sub, ROFFMAC_STRUCT, NULL }, { "ig", roff_block, roff_block_text, roff_block_sub, 0, NULL }, { "it", roff_it, NULL, NULL, 0, NULL }, { "ne", roff_line_ignore, NULL, NULL, 0, NULL }, { "nh", roff_line_ignore, NULL, NULL, 0, NULL }, { "nr", roff_nr, NULL, NULL, 0, NULL }, { "ns", roff_line_ignore, NULL, NULL, 0, NULL }, { "ps", roff_line_ignore, NULL, NULL, 0, NULL }, { "rm", roff_rm, NULL, NULL, 0, NULL }, { "rr", roff_rr, NULL, NULL, 0, NULL }, { "so", roff_so, NULL, NULL, 0, NULL }, { "ta", roff_line_ignore, NULL, NULL, 0, NULL }, { "tr", roff_tr, NULL, NULL, 0, NULL }, { "Dd", roff_Dd, NULL, NULL, 0, NULL }, { "TH", roff_TH, NULL, NULL, 0, NULL }, { "TS", roff_TS, NULL, NULL, 0, NULL }, { "TE", roff_TE, NULL, NULL, 0, NULL }, { "T&", roff_T_, NULL, NULL, 0, NULL }, { "EQ", roff_EQ, NULL, NULL, 0, NULL }, { "EN", roff_EN, NULL, NULL, 0, NULL }, { ".", roff_cblock, NULL, NULL, 0, NULL }, { NULL, roff_userdef, NULL, NULL, 0, NULL }, }; /* not currently implemented: Ds em Eq LP Me PP pp Or Rd Sf SH */ const char *const __mdoc_reserved[] = { "Ac", "Ad", "An", "Ao", "Ap", "Aq", "Ar", "At", "Bc", "Bd", "Bf", "Bk", "Bl", "Bo", "Bq", "Brc", "Bro", "Brq", "Bsx", "Bt", "Bx", "Cd", "Cm", "Db", "Dc", "Dd", "Dl", "Do", "Dq", "Dt", "Dv", "Dx", "D1", "Ec", "Ed", "Ef", "Ek", "El", "Em", "En", "Eo", "Er", "Es", "Ev", "Ex", "Fa", "Fc", "Fd", "Fl", "Fn", "Fo", "Fr", "Ft", "Fx", "Hf", "Ic", "In", "It", "Lb", "Li", "Lk", "Lp", "Ms", "Mt", "Nd", "Nm", "No", "Ns", "Nx", "Oc", "Oo", "Op", "Os", "Ot", "Ox", "Pa", "Pc", "Pf", "Po", "Pp", "Pq", "Qc", "Ql", "Qo", "Qq", "Re", "Rs", "Rv", "Sc", "Sh", "Sm", "So", "Sq", "Ss", "St", "Sx", "Sy", "Ta", "Tn", "Ud", "Ux", "Va", "Vt", "Xc", "Xo", "Xr", "%A", "%B", "%C", "%D", "%I", "%J", "%N", "%O", "%P", "%Q", "%R", "%T", "%U", "%V", NULL }; /* not currently implemented: BT DE DS ME MT PT SY TQ YS */ const char *const __man_reserved[] = { "AT", "B", "BI", "BR", "DT", "EE", "EN", "EQ", "EX", "HP", "I", "IB", "IP", "IR", "LP", "OP", "P", "PD", "PP", "R", "RB", "RE", "RI", "RS", "SB", "SH", "SM", "SS", "TE", "TH", "TP", "TS", "T&", "UC", "UE", "UR", NULL }; /* Array of injected predefined strings. */ #define PREDEFS_MAX 38 static const struct predef predefs[PREDEFS_MAX] = { #include "predefs.in" }; /* See roffhash_find() */ #define ROFF_HASH(p) (p[0] - ASCII_LO) static int roffit_lines; /* number of lines to delay */ static char *roffit_macro; /* nil-terminated macro line */ static void roffhash_init(void) { struct roffmac *n; int buc, i; for (i = 0; i < (int)ROFF_USERDEF; i++) { assert(roffs[i].name[0] >= ASCII_LO); assert(roffs[i].name[0] <= ASCII_HI); buc = ROFF_HASH(roffs[i].name); if (NULL != (n = hash[buc])) { for ( ; n->next; n = n->next) /* Do nothing. */ ; n->next = &roffs[i]; } else hash[buc] = &roffs[i]; } } /* * Look up a roff token by its name. Returns ROFF_MAX if no macro by * the nil-terminated string name could be found. */ static enum rofft roffhash_find(const char *p, size_t s) { int buc; struct roffmac *n; /* * libroff has an extremely simple hashtable, for the time * being, which simply keys on the first character, which must * be printable, then walks a chain. It works well enough until * optimised. */ if (p[0] < ASCII_LO || p[0] > ASCII_HI) return(ROFF_MAX); buc = ROFF_HASH(p); if (NULL == (n = hash[buc])) return(ROFF_MAX); for ( ; n; n = n->next) if (0 == strncmp(n->name, p, s) && '\0' == n->name[(int)s]) return((enum rofft)(n - roffs)); return(ROFF_MAX); } /* * Pop the current node off of the stack of roff instructions currently * pending. */ static void roffnode_pop(struct roff *r) { struct roffnode *p; assert(r->last); p = r->last; r->last = r->last->parent; free(p->name); free(p->end); free(p); } /* * Push a roff node onto the instruction stack. This must later be * removed with roffnode_pop(). */ static void roffnode_push(struct roff *r, enum rofft tok, const char *name, int line, int col) { struct roffnode *p; p = mandoc_calloc(1, sizeof(struct roffnode)); p->tok = tok; if (name) p->name = mandoc_strdup(name); p->parent = r->last; p->line = line; p->col = col; p->rule = p->parent ? p->parent->rule : 0; r->last = p; } static void roff_free1(struct roff *r) { struct tbl_node *tbl; struct eqn_node *e; int i; while (NULL != (tbl = r->first_tbl)) { r->first_tbl = tbl->next; tbl_free(tbl); } r->first_tbl = r->last_tbl = r->tbl = NULL; while (NULL != (e = r->first_eqn)) { r->first_eqn = e->next; eqn_free(e); } r->first_eqn = r->last_eqn = r->eqn = NULL; while (r->last) roffnode_pop(r); roff_freestr(r->strtab); roff_freestr(r->xmbtab); r->strtab = r->xmbtab = NULL; roff_freereg(r->regtab); r->regtab = NULL; if (r->xtab) for (i = 0; i < 128; i++) free(r->xtab[i].p); free(r->xtab); r->xtab = NULL; } void roff_reset(struct roff *r) { roff_free1(r); r->control = 0; } void roff_free(struct roff *r) { roff_free1(r); free(r); } struct roff * roff_alloc(struct mparse *parse, int options) { struct roff *r; r = mandoc_calloc(1, sizeof(struct roff)); r->parse = parse; r->options = options; r->rstackpos = -1; roffhash_init(); return(r); } /* * In the current line, expand escape sequences that tend to get * used in numerical expressions and conditional requests. * Also check the syntax of the remaining escape sequences. */ static enum rofferr roff_res(struct roff *r, char **bufp, size_t *szp, int ln, int pos) { char ubuf[24]; /* buffer to print the number */ const char *start; /* start of the string to process */ char *stesc; /* start of an escape sequence ('\\') */ const char *stnam; /* start of the name, after "[(*" */ const char *cp; /* end of the name, e.g. before ']' */ const char *res; /* the string to be substituted */ char *nbuf; /* new buffer to copy bufp to */ size_t maxl; /* expected length of the escape name */ size_t naml; /* actual length of the escape name */ int expand_count; /* to avoid infinite loops */ int npos; /* position in numeric expression */ int arg_complete; /* argument not interrupted by eol */ char term; /* character terminating the escape */ expand_count = 0; start = *bufp + pos; stesc = strchr(start, '\0') - 1; while (stesc-- > start) { /* Search backwards for the next backslash. */ if ('\\' != *stesc) continue; /* If it is escaped, skip it. */ for (cp = stesc - 1; cp >= start; cp--) if ('\\' != *cp) break; if (0 == (stesc - cp) % 2) { stesc = (char *)cp; continue; } /* Decide whether to expand or to check only. */ term = '\0'; cp = stesc + 1; switch (*cp) { case '*': res = NULL; break; case 'B': /* FALLTHROUGH */ case 'w': term = cp[1]; /* FALLTHROUGH */ case 'n': res = ubuf; break; default: if (ESCAPE_ERROR == mandoc_escape(&cp, NULL, NULL)) mandoc_msg(MANDOCERR_BADESCAPE, r->parse, ln, (int)(stesc - *bufp), NULL); continue; } if (EXPAND_LIMIT < ++expand_count) { mandoc_msg(MANDOCERR_ROFFLOOP, r->parse, ln, (int)(stesc - *bufp), NULL); return(ROFF_IGN); } /* * The third character decides the length * of the name of the string or register. * Save a pointer to the name. */ if ('\0' == term) { switch (*++cp) { case '\0': maxl = 0; break; case '(': cp++; maxl = 2; break; case '[': cp++; term = ']'; maxl = 0; break; default: maxl = 1; break; } } else { cp += 2; maxl = 0; } stnam = cp; /* Advance to the end of the name. */ arg_complete = 1; for (naml = 0; 0 == maxl || naml < maxl; naml++, cp++) { if ('\0' == *cp) { mandoc_msg(MANDOCERR_BADESCAPE, r->parse, ln, (int)(stesc - *bufp), NULL); arg_complete = 0; break; } if (0 == maxl && *cp == term) { cp++; break; } } /* * Retrieve the replacement string; if it is * undefined, resume searching for escapes. */ switch (stesc[1]) { case '*': if (arg_complete) res = roff_getstrn(r, stnam, naml); break; case 'B': npos = 0; ubuf[0] = arg_complete && roff_evalnum(stnam, &npos, NULL, 0) && stnam + npos + 1 == cp ? '1' : '0'; ubuf[1] = '\0'; break; case 'n': if (arg_complete) (void)snprintf(ubuf, sizeof(ubuf), "%d", roff_getregn(r, stnam, naml)); else ubuf[0] = '\0'; break; case 'w': /* use even incomplete args */ (void)snprintf(ubuf, sizeof(ubuf), "%d", 24 * (int)naml); break; } if (NULL == res) { mandoc_msg(MANDOCERR_BADESCAPE, r->parse, ln, (int)(stesc - *bufp), NULL); res = ""; } /* Replace the escape sequence by the string. */ *stesc = '\0'; *szp = mandoc_asprintf(&nbuf, "%s%s%s", *bufp, res, cp) + 1; /* Prepare for the next replacement. */ start = nbuf + pos; stesc = nbuf + (stesc - *bufp) + strlen(res); free(*bufp); *bufp = nbuf; } return(ROFF_CONT); } /* * Process text streams: * Convert all breakable hyphens into ASCII_HYPH. * Decrement and spring input line trap. */ static enum rofferr roff_parsetext(char **bufp, size_t *szp, int pos, int *offs) { size_t sz; const char *start; char *p; int isz; enum mandoc_esc esc; start = p = *bufp + pos; while ('\0' != *p) { sz = strcspn(p, "-\\"); p += sz; if ('\0' == *p) break; if ('\\' == *p) { /* Skip over escapes. */ p++; esc = mandoc_escape((const char **)&p, NULL, NULL); if (ESCAPE_ERROR == esc) break; continue; } else if (p == start) { p++; continue; } if (isalpha((unsigned char)p[-1]) && isalpha((unsigned char)p[1])) *p = ASCII_HYPH; p++; } /* Spring the input line trap. */ if (1 == roffit_lines) { isz = mandoc_asprintf(&p, "%s\n.%s", *bufp, roffit_macro); free(*bufp); *bufp = p; *szp = isz + 1; *offs = 0; free(roffit_macro); roffit_lines = 0; return(ROFF_REPARSE); } else if (1 < roffit_lines) --roffit_lines; return(ROFF_CONT); } enum rofferr roff_parseln(struct roff *r, int ln, char **bufp, size_t *szp, int pos, int *offs) { enum rofft t; enum rofferr e; int ppos, ctl; /* * Run the reserved-word filter only if we have some reserved * words to fill in. */ e = roff_res(r, bufp, szp, ln, pos); if (ROFF_IGN == e) return(e); assert(ROFF_CONT == e); ppos = pos; ctl = roff_getcontrol(r, *bufp, &pos); /* * First, if a scope is open and we're not a macro, pass the * text through the macro's filter. If a scope isn't open and * we're not a macro, just let it through. * Finally, if there's an equation scope open, divert it into it * no matter our state. */ if (r->last && ! ctl) { t = r->last->tok; assert(roffs[t].text); e = (*roffs[t].text)(r, t, bufp, szp, ln, pos, pos, offs); assert(ROFF_IGN == e || ROFF_CONT == e); if (ROFF_CONT != e) return(e); } if (r->eqn) return(eqn_read(&r->eqn, ln, *bufp, ppos, offs)); if ( ! ctl) { if (r->tbl) return(tbl_read(r->tbl, ln, *bufp, pos)); return(roff_parsetext(bufp, szp, pos, offs)); } /* * If a scope is open, go to the child handler for that macro, * as it may want to preprocess before doing anything with it. * Don't do so if an equation is open. */ if (r->last) { t = r->last->tok; assert(roffs[t].sub); return((*roffs[t].sub)(r, t, bufp, szp, ln, ppos, pos, offs)); } /* * Lastly, as we've no scope open, try to look up and execute * the new macro. If no macro is found, simply return and let * the compilers handle it. */ if (ROFF_MAX == (t = roff_parse(r, *bufp, &pos, ln, ppos))) return(ROFF_CONT); assert(roffs[t].proc); return((*roffs[t].proc)(r, t, bufp, szp, ln, ppos, pos, offs)); } void roff_endparse(struct roff *r) { if (r->last) mandoc_msg(MANDOCERR_SCOPEEXIT, r->parse, r->last->line, r->last->col, NULL); if (r->eqn) { mandoc_msg(MANDOCERR_SCOPEEXIT, r->parse, r->eqn->eqn.ln, r->eqn->eqn.pos, NULL); eqn_end(&r->eqn); } if (r->tbl) { mandoc_msg(MANDOCERR_SCOPEEXIT, r->parse, r->tbl->line, r->tbl->pos, NULL); tbl_end(&r->tbl); } } /* * Parse a roff node's type from the input buffer. This must be in the * form of ".foo xxx" in the usual way. */ static enum rofft roff_parse(struct roff *r, char *buf, int *pos, int ln, int ppos) { char *cp; const char *mac; size_t maclen; enum rofft t; cp = buf + *pos; if ('\0' == *cp || '"' == *cp || '\t' == *cp || ' ' == *cp) return(ROFF_MAX); mac = cp; maclen = roff_getname(r, &cp, ln, ppos); t = (r->current_string = roff_getstrn(r, mac, maclen)) ? ROFF_USERDEF : roffhash_find(mac, maclen); if (ROFF_MAX != t) *pos = cp - buf; return(t); } static enum rofferr roff_cblock(ROFF_ARGS) { /* * A block-close `..' should only be invoked as a child of an * ignore macro, otherwise raise a warning and just ignore it. */ if (NULL == r->last) { mandoc_msg(MANDOCERR_NOSCOPE, r->parse, ln, ppos, NULL); return(ROFF_IGN); } switch (r->last->tok) { case ROFF_am: /* FALLTHROUGH */ case ROFF_ami: /* FALLTHROUGH */ case ROFF_am1: /* FALLTHROUGH */ case ROFF_de: /* ROFF_de1 is remapped to ROFF_de in roff_block(). */ /* FALLTHROUGH */ case ROFF_dei: /* FALLTHROUGH */ case ROFF_ig: break; default: mandoc_msg(MANDOCERR_NOSCOPE, r->parse, ln, ppos, NULL); return(ROFF_IGN); } if ((*bufp)[pos]) mandoc_vmsg(MANDOCERR_ARG_SKIP, r->parse, ln, pos, ".. %s", *bufp + pos); roffnode_pop(r); roffnode_cleanscope(r); return(ROFF_IGN); } static void roffnode_cleanscope(struct roff *r) { while (r->last) { if (--r->last->endspan != 0) break; roffnode_pop(r); } } static void roff_ccond(struct roff *r, int ln, int ppos) { if (NULL == r->last) { mandoc_msg(MANDOCERR_NOSCOPE, r->parse, ln, ppos, NULL); return; } switch (r->last->tok) { case ROFF_el: /* FALLTHROUGH */ case ROFF_ie: /* FALLTHROUGH */ case ROFF_if: break; default: mandoc_msg(MANDOCERR_NOSCOPE, r->parse, ln, ppos, NULL); return; } if (r->last->endspan > -1) { mandoc_msg(MANDOCERR_NOSCOPE, r->parse, ln, ppos, NULL); return; } roffnode_pop(r); roffnode_cleanscope(r); return; } static enum rofferr roff_block(ROFF_ARGS) { char *name, *cp; size_t namesz; name = cp = *bufp + pos; namesz = 0; if (ROFF_ig != tok) { if ('\0' == *cp) { mandoc_msg(MANDOCERR_REQ_EMPTY, r->parse, ln, ppos, roffs[tok].name); return(ROFF_IGN); } /* * Re-write `de1', since we don't really care about * groff's strange compatibility mode, into `de'. */ if (ROFF_de1 == tok) tok = ROFF_de; else if (ROFF_de != tok) mandoc_msg(MANDOCERR_REQUEST, r->parse, ln, ppos, roffs[tok].name); namesz = roff_getname(r, &cp, ln, ppos); name[namesz] = '\0'; } else name = NULL; roffnode_push(r, tok, name, ln, ppos); /* * At the beginning of a `de' macro, clear the existing string * with the same name, if there is one. New content will be * appended from roff_block_text() in multiline mode. */ if (namesz && ROFF_de == tok) roff_setstrn(&r->strtab, name, namesz, "", 0, 0); if ('\0' == *cp) return(ROFF_IGN); /* If present, process the custom end-of-line marker. */ name = cp; namesz = roff_getname(r, &cp, ln, ppos); if (namesz) r->last->end = mandoc_strndup(name, namesz); if ('\0' != *cp) mandoc_vmsg(MANDOCERR_ARG_EXCESS, r->parse, ln, pos, ".%s ... %s", roffs[tok].name, cp); return(ROFF_IGN); } static enum rofferr roff_block_sub(ROFF_ARGS) { enum rofft t; int i, j; /* * First check whether a custom macro exists at this level. If * it does, then check against it. This is some of groff's * stranger behaviours. If we encountered a custom end-scope * tag and that tag also happens to be a "real" macro, then we * need to try interpreting it again as a real macro. If it's * not, then return ignore. Else continue. */ if (r->last->end) { for (i = pos, j = 0; r->last->end[j]; j++, i++) if ((*bufp)[i] != r->last->end[j]) break; if ('\0' == r->last->end[j] && ('\0' == (*bufp)[i] || ' ' == (*bufp)[i] || '\t' == (*bufp)[i])) { roffnode_pop(r); roffnode_cleanscope(r); while (' ' == (*bufp)[i] || '\t' == (*bufp)[i]) i++; pos = i; if (ROFF_MAX != roff_parse(r, *bufp, &pos, ln, ppos)) return(ROFF_RERUN); return(ROFF_IGN); } } /* * If we have no custom end-query or lookup failed, then try * pulling it out of the hashtable. */ t = roff_parse(r, *bufp, &pos, ln, ppos); /* * Macros other than block-end are only significant * in `de' blocks; elsewhere, simply throw them away. */ if (ROFF_cblock != t) { if (ROFF_de == tok) roff_setstr(r, r->last->name, *bufp + ppos, 2); return(ROFF_IGN); } assert(roffs[t].proc); return((*roffs[t].proc)(r, t, bufp, szp, ln, ppos, pos, offs)); } static enum rofferr roff_block_text(ROFF_ARGS) { if (ROFF_de == tok) roff_setstr(r, r->last->name, *bufp + pos, 2); return(ROFF_IGN); } static enum rofferr roff_cond_sub(ROFF_ARGS) { enum rofft t; char *ep; int rr; rr = r->last->rule; roffnode_cleanscope(r); t = roff_parse(r, *bufp, &pos, ln, ppos); /* * Fully handle known macros when they are structurally * required or when the conditional evaluated to true. */ if ((ROFF_MAX != t) && (rr || ROFFMAC_STRUCT & roffs[t].flags)) { assert(roffs[t].proc); return((*roffs[t].proc)(r, t, bufp, szp, ln, ppos, pos, offs)); } /* * If `\}' occurs on a macro line without a preceding macro, * drop the line completely. */ ep = *bufp + pos; if ('\\' == ep[0] && '}' == ep[1]) rr = 0; /* Always check for the closing delimiter `\}'. */ while (NULL != (ep = strchr(ep, '\\'))) { if ('}' == *(++ep)) { *ep = '&'; roff_ccond(r, ln, ep - *bufp - 1); } ++ep; } return(rr ? ROFF_CONT : ROFF_IGN); } static enum rofferr roff_cond_text(ROFF_ARGS) { char *ep; int rr; rr = r->last->rule; roffnode_cleanscope(r); ep = *bufp + pos; while (NULL != (ep = strchr(ep, '\\'))) { if ('}' == *(++ep)) { *ep = '&'; roff_ccond(r, ln, ep - *bufp - 1); } ++ep; } return(rr ? ROFF_CONT : ROFF_IGN); } /* * Parse a single signed integer number. Stop at the first non-digit. * If there is at least one digit, return success and advance the * parse point, else return failure and let the parse point unchanged. * Ignore overflows, treat them just like the C language. */ static int roff_getnum(const char *v, int *pos, int *res) { int myres, n, p; if (NULL == res) res = &myres; p = *pos; n = v[p] == '-'; if (n) p++; for (*res = 0; isdigit((unsigned char)v[p]); p++) *res = 10 * *res + v[p] - '0'; if (p == *pos + n) return 0; if (n) *res = -*res; *pos = p; return 1; } /* * Evaluate a string comparison condition. * The first character is the delimiter. * Succeed if the string up to its second occurrence * matches the string up to its third occurence. * Advance the cursor after the third occurrence * or lacking that, to the end of the line. */ static int roff_evalstrcond(const char *v, int *pos) { const char *s1, *s2, *s3; int match; match = 0; s1 = v + *pos; /* initial delimiter */ s2 = s1 + 1; /* for scanning the first string */ s3 = strchr(s2, *s1); /* for scanning the second string */ if (NULL == s3) /* found no middle delimiter */ goto out; while ('\0' != *++s3) { if (*s2 != *s3) { /* mismatch */ s3 = strchr(s3, *s1); break; } if (*s3 == *s1) { /* found the final delimiter */ match = 1; break; } s2++; } out: if (NULL == s3) s3 = strchr(s2, '\0'); else s3++; *pos = s3 - v; return(match); } /* * Evaluate an optionally negated single character, numerical, * or string condition. */ static int roff_evalcond(const char *v, int *pos) { int wanttrue, number; if ('!' == v[*pos]) { wanttrue = 0; (*pos)++; } else wanttrue = 1; switch (v[*pos]) { case 'n': /* FALLTHROUGH */ case 'o': (*pos)++; return(wanttrue); case 'c': /* FALLTHROUGH */ case 'd': /* FALLTHROUGH */ case 'e': /* FALLTHROUGH */ case 'r': /* FALLTHROUGH */ case 't': (*pos)++; return(!wanttrue); default: break; } if (roff_evalnum(v, pos, &number, 0)) return((number > 0) == wanttrue); else return(roff_evalstrcond(v, pos) == wanttrue); } static enum rofferr roff_line_ignore(ROFF_ARGS) { return(ROFF_IGN); } static enum rofferr roff_cond(ROFF_ARGS) { roffnode_push(r, tok, NULL, ln, ppos); /* * An `.el' has no conditional body: it will consume the value * of the current rstack entry set in prior `ie' calls or * defaults to DENY. * * If we're not an `el', however, then evaluate the conditional. */ r->last->rule = ROFF_el == tok ? (r->rstackpos < 0 ? 0 : r->rstack[r->rstackpos--]) : roff_evalcond(*bufp, &pos); /* * An if-else will put the NEGATION of the current evaluated * conditional into the stack of rules. */ if (ROFF_ie == tok) { if (r->rstackpos == RSTACK_MAX - 1) { mandoc_msg(MANDOCERR_MEM, r->parse, ln, ppos, NULL); return(ROFF_ERR); } r->rstack[++r->rstackpos] = !r->last->rule; } /* If the parent has false as its rule, then so do we. */ if (r->last->parent && !r->last->parent->rule) r->last->rule = 0; /* * Determine scope. * If there is nothing on the line after the conditional, * not even whitespace, use next-line scope. */ if ('\0' == (*bufp)[pos]) { r->last->endspan = 2; goto out; } while (' ' == (*bufp)[pos]) pos++; /* An opening brace requests multiline scope. */ if ('\\' == (*bufp)[pos] && '{' == (*bufp)[pos + 1]) { r->last->endspan = -1; pos += 2; goto out; } /* * Anything else following the conditional causes * single-line scope. Warn if the scope contains * nothing but trailing whitespace. */ if ('\0' == (*bufp)[pos]) mandoc_msg(MANDOCERR_COND_EMPTY, r->parse, ln, ppos, roffs[tok].name); r->last->endspan = 1; out: *offs = pos; return(ROFF_RERUN); } static enum rofferr roff_ds(ROFF_ARGS) { char *string; const char *name; size_t namesz; /* * The first word is the name of the string. * If it is empty or terminated by an escape sequence, * abort the `ds' request without defining anything. */ name = string = *bufp + pos; if ('\0' == *name) return(ROFF_IGN); namesz = roff_getname(r, &string, ln, pos); if ('\\' == name[namesz]) return(ROFF_IGN); /* Read past the initial double-quote, if any. */ if ('"' == *string) string++; /* The rest is the value. */ roff_setstrn(&r->strtab, name, namesz, string, strlen(string), ROFF_as == tok); return(ROFF_IGN); } /* * Parse a single operator, one or two characters long. * If the operator is recognized, return success and advance the * parse point, else return failure and let the parse point unchanged. */ static int roff_getop(const char *v, int *pos, char *res) { *res = v[*pos]; switch (*res) { case '+': /* FALLTHROUGH */ case '-': /* FALLTHROUGH */ case '*': /* FALLTHROUGH */ case '/': /* FALLTHROUGH */ case '%': /* FALLTHROUGH */ case '&': /* FALLTHROUGH */ case ':': break; case '<': switch (v[*pos + 1]) { case '=': *res = 'l'; (*pos)++; break; case '>': *res = '!'; (*pos)++; break; case '?': *res = 'i'; (*pos)++; break; default: break; } break; case '>': switch (v[*pos + 1]) { case '=': *res = 'g'; (*pos)++; break; case '?': *res = 'a'; (*pos)++; break; default: break; } break; case '=': if ('=' == v[*pos + 1]) (*pos)++; break; default: return(0); } (*pos)++; return(*res); } /* * Evaluate either a parenthesized numeric expression * or a single signed integer number. */ static int roff_evalpar(const char *v, int *pos, int *res) { if ('(' != v[*pos]) return(roff_getnum(v, pos, res)); (*pos)++; if ( ! roff_evalnum(v, pos, res, 1)) return(0); /* * Omission of the closing parenthesis * is an error in validation mode, * but ignored in evaluation mode. */ if (')' == v[*pos]) (*pos)++; else if (NULL == res) return(0); return(1); } /* * Evaluate a complete numeric expression. * Proceed left to right, there is no concept of precedence. */ static int roff_evalnum(const char *v, int *pos, int *res, int skipwhite) { int mypos, operand2; char operator; if (NULL == pos) { mypos = 0; pos = &mypos; } if (skipwhite) while (isspace((unsigned char)v[*pos])) (*pos)++; if ( ! roff_evalpar(v, pos, res)) return(0); while (1) { if (skipwhite) while (isspace((unsigned char)v[*pos])) (*pos)++; if ( ! roff_getop(v, pos, &operator)) break; if (skipwhite) while (isspace((unsigned char)v[*pos])) (*pos)++; if ( ! roff_evalpar(v, pos, &operand2)) return(0); if (skipwhite) while (isspace((unsigned char)v[*pos])) (*pos)++; if (NULL == res) continue; switch (operator) { case '+': *res += operand2; break; case '-': *res -= operand2; break; case '*': *res *= operand2; break; case '/': *res /= operand2; break; case '%': *res %= operand2; break; case '<': *res = *res < operand2; break; case '>': *res = *res > operand2; break; case 'l': *res = *res <= operand2; break; case 'g': *res = *res >= operand2; break; case '=': *res = *res == operand2; break; case '!': *res = *res != operand2; break; case '&': *res = *res && operand2; break; case ':': *res = *res || operand2; break; case 'i': if (operand2 < *res) *res = operand2; break; case 'a': if (operand2 > *res) *res = operand2; break; default: abort(); } } return(1); } void roff_setreg(struct roff *r, const char *name, int val, char sign) { struct roffreg *reg; /* Search for an existing register with the same name. */ reg = r->regtab; while (reg && strcmp(name, reg->key.p)) reg = reg->next; if (NULL == reg) { /* Create a new register. */ reg = mandoc_malloc(sizeof(struct roffreg)); reg->key.p = mandoc_strdup(name); reg->key.sz = strlen(name); reg->val = 0; reg->next = r->regtab; r->regtab = reg; } if ('+' == sign) reg->val += val; else if ('-' == sign) reg->val -= val; else reg->val = val; } /* * Handle some predefined read-only number registers. * For now, return -1 if the requested register is not predefined; * in case a predefined read-only register having the value -1 * were to turn up, another special value would have to be chosen. */ static int roff_getregro(const char *name) { switch (*name) { case 'A': /* ASCII approximation mode is always off. */ return(0); case 'g': /* Groff compatibility mode is always on. */ return(1); case 'H': /* Fixed horizontal resolution. */ return (24); case 'j': /* Always adjust left margin only. */ return(0); case 'T': /* Some output device is always defined. */ return(1); case 'V': /* Fixed vertical resolution. */ return (40); default: return (-1); } } int roff_getreg(const struct roff *r, const char *name) { struct roffreg *reg; int val; if ('.' == name[0] && '\0' != name[1] && '\0' == name[2]) { val = roff_getregro(name + 1); if (-1 != val) return (val); } for (reg = r->regtab; reg; reg = reg->next) if (0 == strcmp(name, reg->key.p)) return(reg->val); return(0); } static int roff_getregn(const struct roff *r, const char *name, size_t len) { struct roffreg *reg; int val; if ('.' == name[0] && 2 == len) { val = roff_getregro(name + 1); if (-1 != val) return (val); } for (reg = r->regtab; reg; reg = reg->next) if (len == reg->key.sz && 0 == strncmp(name, reg->key.p, len)) return(reg->val); return(0); } static void roff_freereg(struct roffreg *reg) { struct roffreg *old_reg; while (NULL != reg) { free(reg->key.p); old_reg = reg; reg = reg->next; free(old_reg); } } static enum rofferr roff_nr(ROFF_ARGS) { char *key, *val; size_t keysz; int iv; char sign; key = val = *bufp + pos; if ('\0' == *key) return(ROFF_IGN); keysz = roff_getname(r, &val, ln, pos); if ('\\' == key[keysz]) return(ROFF_IGN); key[keysz] = '\0'; sign = *val; if ('+' == sign || '-' == sign) val++; if (roff_evalnum(val, NULL, &iv, 0)) roff_setreg(r, key, iv, sign); return(ROFF_IGN); } static enum rofferr roff_rr(ROFF_ARGS) { struct roffreg *reg, **prev; char *name, *cp; size_t namesz; name = cp = *bufp + pos; if ('\0' == *name) return(ROFF_IGN); namesz = roff_getname(r, &cp, ln, pos); name[namesz] = '\0'; prev = &r->regtab; while (1) { reg = *prev; if (NULL == reg || !strcmp(name, reg->key.p)) break; prev = ®->next; } if (NULL != reg) { *prev = reg->next; free(reg->key.p); free(reg); } return(ROFF_IGN); } static enum rofferr roff_rm(ROFF_ARGS) { const char *name; char *cp; size_t namesz; cp = *bufp + pos; while ('\0' != *cp) { name = cp; namesz = roff_getname(r, &cp, ln, (int)(cp - *bufp)); roff_setstrn(&r->strtab, name, namesz, NULL, 0, 0); if ('\\' == name[namesz]) break; } return(ROFF_IGN); } static enum rofferr roff_it(ROFF_ARGS) { char *cp; size_t len; int iv; /* Parse the number of lines. */ cp = *bufp + pos; len = strcspn(cp, " \t"); cp[len] = '\0'; if ((iv = mandoc_strntoi(cp, len, 10)) <= 0) { mandoc_msg(MANDOCERR_NUMERIC, r->parse, ln, ppos, *bufp + 1); return(ROFF_IGN); } cp += len + 1; /* Arm the input line trap. */ roffit_lines = iv; roffit_macro = mandoc_strdup(cp); return(ROFF_IGN); } static enum rofferr roff_Dd(ROFF_ARGS) { const char *const *cp; if (0 == ((MPARSE_MDOC | MPARSE_QUICK) & r->options)) for (cp = __mdoc_reserved; *cp; cp++) roff_setstr(r, *cp, NULL, 0); return(ROFF_CONT); } static enum rofferr roff_TH(ROFF_ARGS) { const char *const *cp; if (0 == (MPARSE_QUICK & r->options)) for (cp = __man_reserved; *cp; cp++) roff_setstr(r, *cp, NULL, 0); return(ROFF_CONT); } static enum rofferr roff_TE(ROFF_ARGS) { if (NULL == r->tbl) mandoc_msg(MANDOCERR_NOSCOPE, r->parse, ln, ppos, NULL); else tbl_end(&r->tbl); return(ROFF_IGN); } static enum rofferr roff_T_(ROFF_ARGS) { if (NULL == r->tbl) mandoc_msg(MANDOCERR_NOSCOPE, r->parse, ln, ppos, NULL); else tbl_restart(ppos, ln, r->tbl); return(ROFF_IGN); } #if 0 static int roff_closeeqn(struct roff *r) { return(r->eqn && ROFF_EQN == eqn_end(&r->eqn) ? 1 : 0); } #endif static void roff_openeqn(struct roff *r, const char *name, int line, int offs, const char *buf) { struct eqn_node *e; int poff; assert(NULL == r->eqn); e = eqn_alloc(name, offs, line, r->parse); if (r->last_eqn) r->last_eqn->next = e; else r->first_eqn = r->last_eqn = e; r->eqn = r->last_eqn = e; if (buf) { poff = 0; eqn_read(&r->eqn, line, buf, offs, &poff); } } static enum rofferr roff_EQ(ROFF_ARGS) { roff_openeqn(r, *bufp + pos, ln, ppos, NULL); return(ROFF_IGN); } static enum rofferr roff_EN(ROFF_ARGS) { mandoc_msg(MANDOCERR_NOSCOPE, r->parse, ln, ppos, NULL); return(ROFF_IGN); } static enum rofferr roff_TS(ROFF_ARGS) { struct tbl_node *tbl; if (r->tbl) { mandoc_msg(MANDOCERR_SCOPEBROKEN, r->parse, ln, ppos, NULL); tbl_end(&r->tbl); } tbl = tbl_alloc(ppos, ln, r->parse); if (r->last_tbl) r->last_tbl->next = tbl; else r->first_tbl = r->last_tbl = tbl; r->tbl = r->last_tbl = tbl; return(ROFF_IGN); } static enum rofferr roff_cc(ROFF_ARGS) { const char *p; p = *bufp + pos; if ('\0' == *p || '.' == (r->control = *p++)) r->control = 0; if ('\0' != *p) mandoc_msg(MANDOCERR_ARGCOUNT, r->parse, ln, ppos, NULL); return(ROFF_IGN); } static enum rofferr roff_tr(ROFF_ARGS) { const char *p, *first, *second; size_t fsz, ssz; enum mandoc_esc esc; p = *bufp + pos; if ('\0' == *p) { mandoc_msg(MANDOCERR_ARGCOUNT, r->parse, ln, ppos, NULL); return(ROFF_IGN); } while ('\0' != *p) { fsz = ssz = 1; first = p++; if ('\\' == *first) { esc = mandoc_escape(&p, NULL, NULL); if (ESCAPE_ERROR == esc) { mandoc_msg(MANDOCERR_BADESCAPE, r->parse, ln, (int)(p - *bufp), NULL); return(ROFF_IGN); } fsz = (size_t)(p - first); } second = p++; if ('\\' == *second) { esc = mandoc_escape(&p, NULL, NULL); if (ESCAPE_ERROR == esc) { mandoc_msg(MANDOCERR_BADESCAPE, r->parse, ln, (int)(p - *bufp), NULL); return(ROFF_IGN); } ssz = (size_t)(p - second); } else if ('\0' == *second) { mandoc_msg(MANDOCERR_ARGCOUNT, r->parse, ln, (int)(p - *bufp), NULL); second = " "; p--; } if (fsz > 1) { roff_setstrn(&r->xmbtab, first, fsz, second, ssz, 0); continue; } if (NULL == r->xtab) r->xtab = mandoc_calloc(128, sizeof(struct roffstr)); free(r->xtab[(int)*first].p); r->xtab[(int)*first].p = mandoc_strndup(second, ssz); r->xtab[(int)*first].sz = ssz; } return(ROFF_IGN); } static enum rofferr roff_so(ROFF_ARGS) { char *name; name = *bufp + pos; mandoc_vmsg(MANDOCERR_SO, r->parse, ln, ppos, ".so %s", name); /* * Handle `so'. Be EXTREMELY careful, as we shouldn't be * opening anything that's not in our cwd or anything beneath * it. Thus, explicitly disallow traversing up the file-system * or using absolute paths. */ if ('/' == *name || strstr(name, "../") || strstr(name, "/..")) { mandoc_vmsg(MANDOCERR_SO_PATH, r->parse, ln, ppos, ".so %s", name); return(ROFF_ERR); } *offs = pos; return(ROFF_SO); } static enum rofferr roff_userdef(ROFF_ARGS) { const char *arg[9]; char *cp, *n1, *n2; int i; /* * Collect pointers to macro argument strings * and NUL-terminate them. */ cp = *bufp + pos; for (i = 0; i < 9; i++) arg[i] = '\0' == *cp ? "" : mandoc_getarg(r->parse, &cp, ln, &pos); /* * Expand macro arguments. */ *szp = 0; n1 = cp = mandoc_strdup(r->current_string); while (NULL != (cp = strstr(cp, "\\$"))) { i = cp[2] - '1'; if (0 > i || 8 < i) { /* Not an argument invocation. */ cp += 2; continue; } *cp = '\0'; *szp = mandoc_asprintf(&n2, "%s%s%s", n1, arg[i], cp + 3) + 1; cp = n2 + (cp - n1); free(n1); n1 = n2; } /* * Replace the macro invocation * by the expanded macro. */ free(*bufp); *bufp = n1; if (0 == *szp) *szp = strlen(*bufp) + 1; return(*szp > 1 && '\n' == (*bufp)[(int)*szp - 2] ? ROFF_REPARSE : ROFF_APPEND); } static size_t roff_getname(struct roff *r, char **cpp, int ln, int pos) { char *name, *cp; size_t namesz; name = *cpp; if ('\0' == *name) return(0); /* Read until end of name and terminate it with NUL. */ for (cp = name; 1; cp++) { if ('\0' == *cp || ' ' == *cp) { namesz = cp - name; break; } if ('\\' != *cp) continue; namesz = cp - name; if ('{' == cp[1] || '}' == cp[1]) break; cp++; if ('\\' == *cp) continue; mandoc_msg(MANDOCERR_NAMESC, r->parse, ln, pos, NULL); mandoc_escape((const char **)&cp, NULL, NULL); break; } /* Read past spaces. */ while (' ' == *cp) cp++; *cpp = cp; return(namesz); } /* * Store *string into the user-defined string called *name. * To clear an existing entry, call with (*r, *name, NULL, 0). * append == 0: replace mode * append == 1: single-line append mode * append == 2: multiline append mode, append '\n' after each call */ static void roff_setstr(struct roff *r, const char *name, const char *string, int append) { roff_setstrn(&r->strtab, name, strlen(name), string, string ? strlen(string) : 0, append); } static void roff_setstrn(struct roffkv **r, const char *name, size_t namesz, const char *string, size_t stringsz, int append) { struct roffkv *n; char *c; int i; size_t oldch, newch; /* Search for an existing string with the same name. */ n = *r; while (n && (namesz != n->key.sz || strncmp(n->key.p, name, namesz))) n = n->next; if (NULL == n) { /* Create a new string table entry. */ n = mandoc_malloc(sizeof(struct roffkv)); n->key.p = mandoc_strndup(name, namesz); n->key.sz = namesz; n->val.p = NULL; n->val.sz = 0; n->next = *r; *r = n; } else if (0 == append) { free(n->val.p); n->val.p = NULL; n->val.sz = 0; } if (NULL == string) return; /* * One additional byte for the '\n' in multiline mode, * and one for the terminating '\0'. */ newch = stringsz + (1 < append ? 2u : 1u); if (NULL == n->val.p) { n->val.p = mandoc_malloc(newch); *n->val.p = '\0'; oldch = 0; } else { oldch = n->val.sz; n->val.p = mandoc_realloc(n->val.p, oldch + newch); } /* Skip existing content in the destination buffer. */ c = n->val.p + (int)oldch; /* Append new content to the destination buffer. */ i = 0; while (i < (int)stringsz) { /* * Rudimentary roff copy mode: * Handle escaped backslashes. */ if ('\\' == string[i] && '\\' == string[i + 1]) i++; *c++ = string[i++]; } /* Append terminating bytes. */ if (1 < append) *c++ = '\n'; *c = '\0'; n->val.sz = (int)(c - n->val.p); } static const char * roff_getstrn(const struct roff *r, const char *name, size_t len) { const struct roffkv *n; int i; for (n = r->strtab; n; n = n->next) if (0 == strncmp(name, n->key.p, len) && '\0' == n->key.p[(int)len]) return(n->val.p); for (i = 0; i < PREDEFS_MAX; i++) if (0 == strncmp(name, predefs[i].name, len) && '\0' == predefs[i].name[(int)len]) return(predefs[i].str); return(NULL); } static void roff_freestr(struct roffkv *r) { struct roffkv *n, *nn; for (n = r; n; n = nn) { free(n->key.p); free(n->val.p); nn = n->next; free(n); } } const struct tbl_span * roff_span(const struct roff *r) { return(r->tbl ? tbl_span(r->tbl) : NULL); } const struct eqn * roff_eqn(const struct roff *r) { return(r->last_eqn ? &r->last_eqn->eqn : NULL); } /* * Duplicate an input string, making the appropriate character * conversations (as stipulated by `tr') along the way. * Returns a heap-allocated string with all the replacements made. */ char * roff_strdup(const struct roff *r, const char *p) { const struct roffkv *cp; char *res; const char *pp; size_t ssz, sz; enum mandoc_esc esc; if (NULL == r->xmbtab && NULL == r->xtab) return(mandoc_strdup(p)); else if ('\0' == *p) return(mandoc_strdup("")); /* * Step through each character looking for term matches * (remember that a `tr' can be invoked with an escape, which is * a glyph but the escape is multi-character). * We only do this if the character hash has been initialised * and the string is >0 length. */ res = NULL; ssz = 0; while ('\0' != *p) { if ('\\' != *p && r->xtab && r->xtab[(int)*p].p) { sz = r->xtab[(int)*p].sz; res = mandoc_realloc(res, ssz + sz + 1); memcpy(res + ssz, r->xtab[(int)*p].p, sz); ssz += sz; p++; continue; } else if ('\\' != *p) { res = mandoc_realloc(res, ssz + 2); res[ssz++] = *p++; continue; } /* Search for term matches. */ for (cp = r->xmbtab; cp; cp = cp->next) if (0 == strncmp(p, cp->key.p, cp->key.sz)) break; if (NULL != cp) { /* * A match has been found. * Append the match to the array and move * forward by its keysize. */ res = mandoc_realloc(res, ssz + cp->val.sz + 1); memcpy(res + ssz, cp->val.p, cp->val.sz); ssz += cp->val.sz; p += (int)cp->key.sz; continue; } /* * Handle escapes carefully: we need to copy * over just the escape itself, or else we might * do replacements within the escape itself. * Make sure to pass along the bogus string. */ pp = p++; esc = mandoc_escape(&p, NULL, NULL); if (ESCAPE_ERROR == esc) { sz = strlen(pp); res = mandoc_realloc(res, ssz + sz + 1); memcpy(res + ssz, pp, sz); break; } /* * We bail out on bad escapes. * No need to warn: we already did so when * roff_res() was called. */ sz = (int)(p - pp); res = mandoc_realloc(res, ssz + sz + 1); memcpy(res + ssz, pp, sz); ssz += sz; } res[(int)ssz] = '\0'; return(res); } /* * Find out whether a line is a macro line or not. * If it is, adjust the current position and return one; if it isn't, * return zero and don't change the current position. * If the control character has been set with `.cc', then let that grain * precedence. * This is slighly contrary to groff, where using the non-breaking * control character when `cc' has been invoked will cause the * non-breaking macro contents to be printed verbatim. */ int roff_getcontrol(const struct roff *r, const char *cp, int *ppos) { int pos; pos = *ppos; if (0 != r->control && cp[pos] == r->control) pos++; else if (0 != r->control) return(0); else if ('\\' == cp[pos] && '.' == cp[pos + 1]) pos += 2; else if ('.' == cp[pos] || '\'' == cp[pos]) pos++; else return(0); while (' ' == cp[pos] || '\t' == cp[pos]) pos++; *ppos = pos; return(1); }