/* $Header: /cvs/gridengine/source/3rdparty/qtcsh/sh.parse.c,v 1.1.1.1 2001/07/18 11:06:05 root Exp $ */ /* * sh.parse.c: Interpret a list of tokens */ /*- * Copyright (c) 1980, 1991 The Regents of the University of California. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include "sh.h" RCSID("$Id: sh.parse.c,v 1.1.1.1 2001/07/18 11:06:05 root Exp $") /* * C shell */ static void asyntax __P((struct wordent *, struct wordent *)); static void asyn0 __P((struct wordent *, struct wordent *)); static void asyn3 __P((struct wordent *, struct wordent *)); static struct wordent *freenod __P((struct wordent *, struct wordent *)); static struct command *syn0 __P((struct wordent *, struct wordent *, int)); static struct command *syn1 __P((struct wordent *, struct wordent *, int)); static struct command *syn1a __P((struct wordent *, struct wordent *, int)); static struct command *syn1b __P((struct wordent *, struct wordent *, int)); static struct command *syn2 __P((struct wordent *, struct wordent *, int)); static struct command *syn3 __P((struct wordent *, struct wordent *, int)); #define ALEFT 51 /* max of 50 alias expansions */ #define HLEFT 11 /* max of 10 history expansions */ /* * Perform aliasing on the word list lexp * Do a (very rudimentary) parse to separate into commands. * If word 0 of a command has an alias, do it. * Repeat a maximum of 50 times. */ static int aleft; extern int hleft; void alias(lexp) register struct wordent *lexp; { jmp_buf_t osetexit; aleft = ALEFT; hleft = HLEFT; getexit(osetexit); (void) setexit(); if (haderr) { resexit(osetexit); reset(); } if (--aleft == 0) stderror(ERR_ALIASLOOP); asyntax(lexp->next, lexp); resexit(osetexit); } static void asyntax(p1, p2) register struct wordent *p1, *p2; { while (p1 != p2) if (any(";&\n", p1->word[0])) p1 = p1->next; else { asyn0(p1, p2); return; } } static void asyn0(p1, p2) struct wordent *p1; register struct wordent *p2; { register struct wordent *p; register int l = 0; for (p = p1; p != p2; p = p->next) switch (p->word[0]) { case '(': l++; continue; case ')': l--; if (l < 0) stderror(ERR_TOOMANYRP); continue; case '>': if (p->next != p2 && eq(p->next->word, STRand)) p = p->next; continue; case '&': case '|': case ';': case '\n': if (l != 0) continue; asyn3(p1, p); asyntax(p->next, p2); return; default: break; } if (l == 0) asyn3(p1, p2); } static void asyn3(p1, p2) struct wordent *p1; register struct wordent *p2; { register struct varent *ap; struct wordent alout; register bool redid; if (p1 == p2) return; if (p1->word[0] == '(') { for (p2 = p2->prev; p2->word[0] != ')'; p2 = p2->prev) if (p2 == p1) return; if (p2 == p1->next) return; asyn0(p1->next, p2); return; } ap = adrof1(p1->word, &aliases); if (ap == 0) return; alhistp = p1->prev; alhistt = p2; alvec = ap->vec; redid = lex(&alout); alhistp = alhistt = 0; alvec = 0; if (seterr) { freelex(&alout); stderror(ERR_OLD); } if (p1->word[0] && eq(p1->word, alout.next->word)) { Char *cp = alout.next->word; alout.next->word = Strspl(STRQNULL, cp); xfree((ptr_t) cp); } p1 = freenod(p1, redid ? p2 : p1->next); if (alout.next != &alout) { p1->next->prev = alout.prev->prev; alout.prev->prev->next = p1->next; alout.next->prev = p1; p1->next = alout.next; xfree((ptr_t) alout.prev->word); xfree((ptr_t) (alout.prev)); } reset(); /* throw! */ } static struct wordent * freenod(p1, p2) register struct wordent *p1, *p2; { register struct wordent *retp = p1->prev; while (p1 != p2) { xfree((ptr_t) p1->word); p1 = p1->next; xfree((ptr_t) (p1->prev)); } retp->next = p2; p2->prev = retp; return (retp); } #define P_HERE 1 #define P_IN 2 #define P_OUT 4 #define P_DIAG 8 /* * syntax * empty * syn0 */ struct command * syntax(p1, p2, flags) register struct wordent *p1, *p2; int flags; { while (p1 != p2) if (any(";&\n", p1->word[0])) p1 = p1->next; else return (syn0(p1, p2, flags)); return (0); } /* * syn0 * syn1 * syn1 & syntax */ static struct command * syn0(p1, p2, flags) struct wordent *p1, *p2; int flags; { register struct wordent *p; register struct command *t, *t1; int l; l = 0; for (p = p1; p != p2; p = p->next) switch (p->word[0]) { case '(': l++; continue; case ')': l--; if (l < 0) seterror(ERR_TOOMANYRP); continue; case '|': if (p->word[1] == '|') continue; /*FALLTHROUGH*/ case '>': if (p->next != p2 && eq(p->next->word, STRand)) p = p->next; continue; case '&': if (l != 0) break; if (p->word[1] == '&') continue; t1 = syn1(p1, p, flags); if (t1->t_dtyp == NODE_LIST || t1->t_dtyp == NODE_AND || t1->t_dtyp == NODE_OR) { t = (struct command *) xcalloc(1, sizeof(*t)); t->t_dtyp = NODE_PAREN; t->t_dflg = F_AMPERSAND | F_NOINTERRUPT; t->t_dspr = t1; t1 = t; } else t1->t_dflg |= F_AMPERSAND | F_NOINTERRUPT; t = (struct command *) xcalloc(1, sizeof(*t)); t->t_dtyp = NODE_LIST; t->t_dflg = 0; t->t_dcar = t1; t->t_dcdr = syntax(p, p2, flags); return (t); default: break; } if (l == 0) return (syn1(p1, p2, flags)); seterror(ERR_TOOMANYLP); return (0); } /* * syn1 * syn1a * syn1a ; syntax */ static struct command * syn1(p1, p2, flags) struct wordent *p1, *p2; int flags; { register struct wordent *p; register struct command *t; int l; l = 0; for (p = p1; p != p2; p = p->next) switch (p->word[0]) { case '(': l++; continue; case ')': l--; continue; case ';': case '\n': if (l != 0) break; t = (struct command *) xcalloc(1, sizeof(*t)); t->t_dtyp = NODE_LIST; t->t_dcar = syn1a(p1, p, flags); t->t_dcdr = syntax(p->next, p2, flags); if (t->t_dcdr == 0) t->t_dcdr = t->t_dcar, t->t_dcar = 0; return (t); default: break; } return (syn1a(p1, p2, flags)); } /* * syn1a * syn1b * syn1b || syn1a */ static struct command * syn1a(p1, p2, flags) struct wordent *p1, *p2; int flags; { register struct wordent *p; register struct command *t; register int l = 0; for (p = p1; p != p2; p = p->next) switch (p->word[0]) { case '(': l++; continue; case ')': l--; continue; case '|': if (p->word[1] != '|') continue; if (l == 0) { t = (struct command *) xcalloc(1, sizeof(*t)); t->t_dtyp = NODE_OR; t->t_dcar = syn1b(p1, p, flags); t->t_dcdr = syn1a(p->next, p2, flags); t->t_dflg = 0; return (t); } continue; default: break; } return (syn1b(p1, p2, flags)); } /* * syn1b * syn2 * syn2 && syn1b */ static struct command * syn1b(p1, p2, flags) struct wordent *p1, *p2; int flags; { register struct wordent *p; register struct command *t; register int l = 0; for (p = p1; p != p2; p = p->next) switch (p->word[0]) { case '(': l++; continue; case ')': l--; continue; case '&': if (p->word[1] == '&' && l == 0) { t = (struct command *) xcalloc(1, sizeof(*t)); t->t_dtyp = NODE_AND; t->t_dcar = syn2(p1, p, flags); t->t_dcdr = syn1b(p->next, p2, flags); t->t_dflg = 0; return (t); } continue; default: break; } return (syn2(p1, p2, flags)); } /* * syn2 * syn3 * syn3 | syn2 * syn3 |& syn2 */ static struct command * syn2(p1, p2, flags) struct wordent *p1, *p2; int flags; { register struct wordent *p, *pn; register struct command *t; register int l = 0; int f; for (p = p1; p != p2; p = p->next) switch (p->word[0]) { case '(': l++; continue; case ')': l--; continue; case '|': if (l != 0) continue; t = (struct command *) xcalloc(1, sizeof(*t)); f = flags | P_OUT; pn = p->next; if (pn != p2 && pn->word[0] == '&') { f |= P_DIAG; t->t_dflg |= F_STDERR; } t->t_dtyp = NODE_PIPE; t->t_dcar = syn3(p1, p, f); if (pn != p2 && pn->word[0] == '&') p = pn; t->t_dcdr = syn2(p->next, p2, flags | P_IN); return (t); default: break; } return (syn3(p1, p2, flags)); } static char RELPAR[] = {'<', '>', '(', ')', '\0'}; /* * syn3 * ( syn0 ) [ < in ] [ > out ] * word word* [ < in ] [ > out ] * KEYWORD ( word* ) word* [ < in ] [ > out ] * * KEYWORD = (@ exit foreach if set switch test while) */ static struct command * syn3(p1, p2, flags) struct wordent *p1, *p2; int flags; { register struct wordent *p; struct wordent *lp, *rp; register struct command *t; register int l; Char **av; int n, c; bool specp = 0; if (p1 != p2) { p = p1; again: switch (srchx(p->word)) { case TC_ELSE: p = p->next; if (p != p2) goto again; break; case TC_EXIT: case TC_FOREACH: case TC_IF: case TC_LET: case TC_SET: case TC_SWITCH: case TC_WHILE: specp = 1; break; default: break; } } n = 0; l = 0; for (p = p1; p != p2; p = p->next) switch (p->word[0]) { case '(': if (specp) n++; l++; continue; case ')': if (specp) n++; l--; continue; case '>': case '<': if (l != 0) { if (specp) n++; continue; } if (p->next == p2) continue; if (any(RELPAR, p->next->word[0])) continue; n--; continue; default: if (!specp && l != 0) continue; n++; continue; } if (n < 0) n = 0; t = (struct command *) xcalloc(1, sizeof(*t)); av = (Char **) xcalloc((size_t) (n + 1), sizeof(Char **)); t->t_dcom = av; n = 0; if (p2->word[0] == ')') t->t_dflg = F_NOFORK; lp = 0; rp = 0; l = 0; for (p = p1; p != p2; p = p->next) { c = p->word[0]; switch (c) { case '(': if (l == 0) { if (lp != 0 && !specp) seterror(ERR_BADPLP); lp = p->next; } l++; goto savep; case ')': l--; if (l == 0) rp = p; goto savep; case '>': if (l != 0) goto savep; if (p->word[1] == '>') t->t_dflg |= F_APPEND; if (p->next != p2 && eq(p->next->word, STRand)) { t->t_dflg |= F_STDERR, p = p->next; if (flags & (P_OUT | P_DIAG)) { seterror(ERR_OUTRED); continue; } } if (p->next != p2 && eq(p->next->word, STRbang)) t->t_dflg |= F_OVERWRITE, p = p->next; if (p->next == p2) { seterror(ERR_MISRED); continue; } p = p->next; if (any(RELPAR, p->word[0])) { seterror(ERR_MISRED); continue; } if (((flags & P_OUT) && (flags & P_DIAG) == 0) || t->t_drit) seterror(ERR_OUTRED); else t->t_drit = Strsave(p->word); continue; case '<': if (l != 0) goto savep; if (p->word[1] == '<') t->t_dflg |= F_READ; if (p->next == p2) { seterror(ERR_MISRED); continue; } p = p->next; if (any(RELPAR, p->word[0])) { seterror(ERR_MISRED); continue; } if ((flags & P_HERE) && (t->t_dflg & F_READ)) seterror(ERR_REDPAR); else if ((flags & P_IN) || t->t_dlef) seterror(ERR_INRED); else t->t_dlef = Strsave(p->word); continue; savep: if (!specp) continue; default: if (l != 0 && !specp) continue; if (seterr == 0) av[n] = Strsave(p->word); n++; continue; } } if (lp != 0 && !specp) { if (n != 0) seterror(ERR_BADPLPS); t->t_dtyp = NODE_PAREN; t->t_dspr = syn0(lp, rp, P_HERE); } else { if (n == 0) seterror(ERR_NULLCOM); t->t_dtyp = NODE_COMMAND; } return (t); } void freesyn(t) register struct command *t; { register Char **v; if (t == 0) return; switch (t->t_dtyp) { case NODE_COMMAND: for (v = t->t_dcom; *v; v++) xfree((ptr_t) * v); xfree((ptr_t) (t->t_dcom)); xfree((ptr_t) t->t_dlef); xfree((ptr_t) t->t_drit); break; case NODE_PAREN: freesyn(t->t_dspr); xfree((ptr_t) t->t_dlef); xfree((ptr_t) t->t_drit); break; case NODE_AND: case NODE_OR: case NODE_PIPE: case NODE_LIST: freesyn(t->t_dcar), freesyn(t->t_dcdr); break; default: break; } xfree((ptr_t) t); }