/* * eval.c - gawk parse tree interpreter */ /* * Copyright (C) 1986, 1988, 1989, 1991, 1992 the Free Software Foundation, Inc. * * This file is part of GAWK, the GNU implementation of the * AWK Progamming Language. * * GAWK is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * GAWK is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GAWK; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #ifndef lint static char rcsid[] = "$Id: eval.c,v 1.2 1993/08/02 17:29:38 mycroft Exp $"; #endif /* not lint */ #include "awk.h" extern double pow P((double x, double y)); extern double modf P((double x, double *yp)); extern double fmod P((double x, double y)); static int eval_condition P((NODE *tree)); static NODE *op_assign P((NODE *tree)); static NODE *func_call P((NODE *name, NODE *arg_list)); static NODE *match_op P((NODE *tree)); NODE *_t; /* used as a temporary in macros */ #ifdef MSDOS double _msc51bug; /* to get around a bug in MSC 5.1 */ #endif NODE *ret_node; int OFSlen; int ORSlen; int OFMTidx; int CONVFMTidx; /* Macros and variables to save and restore function and loop bindings */ /* * the val variable allows return/continue/break-out-of-context to be * caught and diagnosed */ #define PUSH_BINDING(stack, x, val) (memcpy ((char *)(stack), (char *)(x), sizeof (jmp_buf)), val++) #define RESTORE_BINDING(stack, x, val) (memcpy ((char *)(x), (char *)(stack), sizeof (jmp_buf)), val--) static jmp_buf loop_tag; /* always the current binding */ static int loop_tag_valid = 0; /* nonzero when loop_tag valid */ static int func_tag_valid = 0; static jmp_buf func_tag; extern int exiting, exit_val; /* * This table is used by the regexp routines to do case independant * matching. Basically, every ascii character maps to itself, except * uppercase letters map to lower case ones. This table has 256 * entries, which may be overkill. Note also that if the system this * is compiled on doesn't use 7-bit ascii, casetable[] should not be * defined to the linker, so gawk should not load. * * Do NOT make this array static, it is used in several spots, not * just in this file. */ #if 'a' == 97 /* it's ascii */ char casetable[] = { '\000', '\001', '\002', '\003', '\004', '\005', '\006', '\007', '\010', '\011', '\012', '\013', '\014', '\015', '\016', '\017', '\020', '\021', '\022', '\023', '\024', '\025', '\026', '\027', '\030', '\031', '\032', '\033', '\034', '\035', '\036', '\037', /* ' ' '!' '"' '#' '$' '%' '&' ''' */ '\040', '\041', '\042', '\043', '\044', '\045', '\046', '\047', /* '(' ')' '*' '+' ',' '-' '.' '/' */ '\050', '\051', '\052', '\053', '\054', '\055', '\056', '\057', /* '0' '1' '2' '3' '4' '5' '6' '7' */ '\060', '\061', '\062', '\063', '\064', '\065', '\066', '\067', /* '8' '9' ':' ';' '<' '=' '>' '?' */ '\070', '\071', '\072', '\073', '\074', '\075', '\076', '\077', /* '@' 'A' 'B' 'C' 'D' 'E' 'F' 'G' */ '\100', '\141', '\142', '\143', '\144', '\145', '\146', '\147', /* 'H' 'I' 'J' 'K' 'L' 'M' 'N' 'O' */ '\150', '\151', '\152', '\153', '\154', '\155', '\156', '\157', /* 'P' 'Q' 'R' 'S' 'T' 'U' 'V' 'W' */ '\160', '\161', '\162', '\163', '\164', '\165', '\166', '\167', /* 'X' 'Y' 'Z' '[' '\' ']' '^' '_' */ '\170', '\171', '\172', '\133', '\134', '\135', '\136', '\137', /* '`' 'a' 'b' 'c' 'd' 'e' 'f' 'g' */ '\140', '\141', '\142', '\143', '\144', '\145', '\146', '\147', /* 'h' 'i' 'j' 'k' 'l' 'm' 'n' 'o' */ '\150', '\151', '\152', '\153', '\154', '\155', '\156', '\157', /* 'p' 'q' 'r' 's' 't' 'u' 'v' 'w' */ '\160', '\161', '\162', '\163', '\164', '\165', '\166', '\167', /* 'x' 'y' 'z' '{' '|' '}' '~' */ '\170', '\171', '\172', '\173', '\174', '\175', '\176', '\177', '\200', '\201', '\202', '\203', '\204', '\205', '\206', '\207', '\210', '\211', '\212', '\213', '\214', '\215', '\216', '\217', '\220', '\221', '\222', '\223', '\224', '\225', '\226', '\227', '\230', '\231', '\232', '\233', '\234', '\235', '\236', '\237', '\240', '\241', '\242', '\243', '\244', '\245', '\246', '\247', '\250', '\251', '\252', '\253', '\254', '\255', '\256', '\257', '\260', '\261', '\262', '\263', '\264', '\265', '\266', '\267', '\270', '\271', '\272', '\273', '\274', '\275', '\276', '\277', '\300', '\301', '\302', '\303', '\304', '\305', '\306', '\307', '\310', '\311', '\312', '\313', '\314', '\315', '\316', '\317', '\320', '\321', '\322', '\323', '\324', '\325', '\326', '\327', '\330', '\331', '\332', '\333', '\334', '\335', '\336', '\337', '\340', '\341', '\342', '\343', '\344', '\345', '\346', '\347', '\350', '\351', '\352', '\353', '\354', '\355', '\356', '\357', '\360', '\361', '\362', '\363', '\364', '\365', '\366', '\367', '\370', '\371', '\372', '\373', '\374', '\375', '\376', '\377', }; #else #include "You lose. You will need a translation table for your character set." #endif /* * Tree is a bunch of rules to run. Returns zero if it hit an exit() * statement */ int interpret(tree) register NODE *volatile tree; { jmp_buf volatile loop_tag_stack; /* shallow binding stack for loop_tag */ static jmp_buf rule_tag; /* tag the rule currently being run, for NEXT * and EXIT statements. It is static because * there are no nested rules */ register NODE *volatile t = NULL; /* temporary */ NODE **volatile lhs; /* lhs == Left Hand Side for assigns, etc */ NODE *volatile stable_tree; int volatile traverse = 1; /* True => loop thru tree (Node_rule_list) */ if (tree == NULL) return 1; sourceline = tree->source_line; source = tree->source_file; switch (tree->type) { case Node_rule_node: traverse = 0; /* False => one for-loop iteration only */ /* FALL THROUGH */ case Node_rule_list: for (t = tree; t != NULL; t = t->rnode) { if (traverse) tree = t->lnode; sourceline = tree->source_line; source = tree->source_file; switch (setjmp(rule_tag)) { case 0: /* normal non-jump */ /* test pattern, if any */ if (tree->lnode == NULL || eval_condition(tree->lnode)) (void) interpret(tree->rnode); break; case TAG_CONTINUE: /* NEXT statement */ return 1; case TAG_BREAK: return 0; default: cant_happen(); } if (!traverse) /* case Node_rule_node */ break; /* don't loop */ } break; case Node_statement_list: for (t = tree; t != NULL; t = t->rnode) (void) interpret(t->lnode); break; case Node_K_if: if (eval_condition(tree->lnode)) { (void) interpret(tree->rnode->lnode); } else { (void) interpret(tree->rnode->rnode); } break; case Node_K_while: PUSH_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); stable_tree = tree; while (eval_condition(stable_tree->lnode)) { switch (setjmp(loop_tag)) { case 0: /* normal non-jump */ (void) interpret(stable_tree->rnode); break; case TAG_CONTINUE: /* continue statement */ break; case TAG_BREAK: /* break statement */ RESTORE_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); return 1; default: cant_happen(); } } RESTORE_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); break; case Node_K_do: PUSH_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); stable_tree = tree; do { switch (setjmp(loop_tag)) { case 0: /* normal non-jump */ (void) interpret(stable_tree->rnode); break; case TAG_CONTINUE: /* continue statement */ break; case TAG_BREAK: /* break statement */ RESTORE_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); return 1; default: cant_happen(); } } while (eval_condition(stable_tree->lnode)); RESTORE_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); break; case Node_K_for: PUSH_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); (void) interpret(tree->forloop->init); stable_tree = tree; while (eval_condition(stable_tree->forloop->cond)) { switch (setjmp(loop_tag)) { case 0: /* normal non-jump */ (void) interpret(stable_tree->lnode); /* fall through */ case TAG_CONTINUE: /* continue statement */ (void) interpret(stable_tree->forloop->incr); break; case TAG_BREAK: /* break statement */ RESTORE_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); return 1; default: cant_happen(); } } RESTORE_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); break; case Node_K_arrayfor: { volatile struct search l; /* For array_for */ Func_ptr after_assign = NULL; #define hakvar forloop->init #define arrvar forloop->incr PUSH_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); lhs = get_lhs(tree->hakvar, &after_assign); t = tree->arrvar; if (t->type == Node_param_list) t = stack_ptr[t->param_cnt]; stable_tree = tree; for (assoc_scan(t, (struct search *)&l); l.retval; assoc_next((struct search *)&l)) { unref(*((NODE **) lhs)); *lhs = dupnode(l.retval); if (after_assign) (*after_assign)(); switch (setjmp(loop_tag)) { case 0: (void) interpret(stable_tree->lnode); case TAG_CONTINUE: break; case TAG_BREAK: RESTORE_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); return 1; default: cant_happen(); } } RESTORE_BINDING(loop_tag_stack, loop_tag, loop_tag_valid); break; } case Node_K_break: if (loop_tag_valid == 0) fatal("unexpected break"); longjmp(loop_tag, TAG_BREAK); break; case Node_K_continue: if (loop_tag_valid == 0) { /* * AT&T nawk treats continue outside of loops like * next. Allow it if not posix, and complain if * lint. */ static int warned = 0; if (do_lint && ! warned) { warning("use of `continue' outside of loop is not portable"); warned = 1; } if (do_posix) fatal("use of `continue' outside of loop is not allowed"); longjmp(rule_tag, TAG_CONTINUE); } else longjmp(loop_tag, TAG_CONTINUE); break; case Node_K_print: do_print(tree); break; case Node_K_printf: do_printf(tree); break; case Node_K_delete: do_delete(tree->lnode, tree->rnode); break; case Node_K_next: longjmp(rule_tag, TAG_CONTINUE); break; case Node_K_nextfile: do_nextfile(); break; case Node_K_exit: /* * In A,K,&W, p. 49, it says that an exit statement "... * causes the program to behave as if the end of input had * occurred; no more input is read, and the END actions, if * any are executed." This implies that the rest of the rules * are not done. So we immediately break out of the main loop. */ exiting = 1; if (tree) { t = tree_eval(tree->lnode); exit_val = (int) force_number(t); } free_temp(t); longjmp(rule_tag, TAG_BREAK); break; case Node_K_return: t = tree_eval(tree->lnode); ret_node = dupnode(t); free_temp(t); longjmp(func_tag, TAG_RETURN); break; default: /* * Appears to be an expression statement. Throw away the * value. */ if (do_lint && tree->type == Node_var) warning("statement has no effect"); t = tree_eval(tree); free_temp(t); break; } return 1; } /* evaluate a subtree */ NODE * r_tree_eval(tree) register NODE *tree; { register NODE *r, *t1, *t2; /* return value & temporary subtrees */ register NODE **lhs; register int di; AWKNUM x, x1, x2; long lx; #ifdef CRAY long lx2; #endif #ifdef DEBUG if (tree == NULL) return Nnull_string; if (tree->type == Node_val) { if (tree->stref <= 0) cant_happen(); return tree; } if (tree->type == Node_var) { if (tree->var_value->stref <= 0) cant_happen(); return tree->var_value; } if (tree->type == Node_param_list) { if (stack_ptr[tree->param_cnt] == NULL) return Nnull_string; else return stack_ptr[tree->param_cnt]->var_value; } #endif switch (tree->type) { case Node_and: return tmp_number((AWKNUM) (eval_condition(tree->lnode) && eval_condition(tree->rnode))); case Node_or: return tmp_number((AWKNUM) (eval_condition(tree->lnode) || eval_condition(tree->rnode))); case Node_not: return tmp_number((AWKNUM) ! eval_condition(tree->lnode)); /* Builtins */ case Node_builtin: return ((*tree->proc) (tree->subnode)); case Node_K_getline: return (do_getline(tree)); case Node_in_array: return tmp_number((AWKNUM) in_array(tree->lnode, tree->rnode)); case Node_func_call: return func_call(tree->rnode, tree->lnode); /* unary operations */ case Node_NR: case Node_FNR: case Node_NF: case Node_FIELDWIDTHS: case Node_FS: case Node_RS: case Node_field_spec: case Node_subscript: case Node_IGNORECASE: case Node_OFS: case Node_ORS: case Node_OFMT: case Node_CONVFMT: lhs = get_lhs(tree, (Func_ptr *)0); return *lhs; case Node_var_array: fatal("attempt to use an array in a scalar context"); case Node_unary_minus: t1 = tree_eval(tree->subnode); x = -force_number(t1); free_temp(t1); return tmp_number(x); case Node_cond_exp: if (eval_condition(tree->lnode)) return tree_eval(tree->rnode->lnode); return tree_eval(tree->rnode->rnode); case Node_match: case Node_nomatch: case Node_regex: return match_op(tree); case Node_func: fatal("function `%s' called with space between name and (,\n%s", tree->lnode->param, "or used in other expression context"); /* assignments */ case Node_assign: { Func_ptr after_assign = NULL; r = tree_eval(tree->rnode); lhs = get_lhs(tree->lnode, &after_assign); if (r != *lhs) { NODE *save; save = *lhs; *lhs = dupnode(r); unref(save); } free_temp(r); if (after_assign) (*after_assign)(); return *lhs; } case Node_concat: { #define STACKSIZE 10 NODE *stack[STACKSIZE]; register NODE **sp; register int len; char *str; register char *dest; sp = stack; len = 0; while (tree->type == Node_concat) { *sp = force_string(tree_eval(tree->lnode)); tree = tree->rnode; len += (*sp)->stlen; if (++sp == &stack[STACKSIZE-2]) /* one more and NULL */ break; } *sp = force_string(tree_eval(tree)); len += (*sp)->stlen; *++sp = NULL; emalloc(str, char *, len+2, "tree_eval"); dest = str; sp = stack; while (*sp) { memcpy(dest, (*sp)->stptr, (*sp)->stlen); dest += (*sp)->stlen; free_temp(*sp); sp++; } r = make_str_node(str, len, ALREADY_MALLOCED); r->flags |= TEMP; } return r; /* other assignment types are easier because they are numeric */ case Node_preincrement: case Node_predecrement: case Node_postincrement: case Node_postdecrement: case Node_assign_exp: case Node_assign_times: case Node_assign_quotient: case Node_assign_mod: case Node_assign_plus: case Node_assign_minus: return op_assign(tree); default: break; /* handled below */ } /* evaluate subtrees in order to do binary operation, then keep going */ t1 = tree_eval(tree->lnode); t2 = tree_eval(tree->rnode); switch (tree->type) { case Node_geq: case Node_leq: case Node_greater: case Node_less: case Node_notequal: case Node_equal: di = cmp_nodes(t1, t2); free_temp(t1); free_temp(t2); switch (tree->type) { case Node_equal: return tmp_number((AWKNUM) (di == 0)); case Node_notequal: return tmp_number((AWKNUM) (di != 0)); case Node_less: return tmp_number((AWKNUM) (di < 0)); case Node_greater: return tmp_number((AWKNUM) (di > 0)); case Node_leq: return tmp_number((AWKNUM) (di <= 0)); case Node_geq: return tmp_number((AWKNUM) (di >= 0)); default: cant_happen(); } break; default: break; /* handled below */ } x1 = force_number(t1); free_temp(t1); x2 = force_number(t2); free_temp(t2); switch (tree->type) { case Node_exp: if ((lx = x2) == x2 && lx >= 0) { /* integer exponent */ if (lx == 0) x = 1; else if (lx == 1) x = x1; else { /* doing it this way should be more precise */ for (x = x1; --lx; ) x *= x1; } } else x = pow((double) x1, (double) x2); return tmp_number(x); case Node_times: return tmp_number(x1 * x2); case Node_quotient: if (x2 == 0) fatal("division by zero attempted"); #ifdef _CRAY /* * special case for integer division, put in for Cray */ lx2 = x2; if (lx2 == 0) return tmp_number(x1 / x2); lx = (long) x1 / lx2; if (lx * x2 == x1) return tmp_number((AWKNUM) lx); else #endif return tmp_number(x1 / x2); case Node_mod: if (x2 == 0) fatal("division by zero attempted in mod"); #ifndef FMOD_MISSING return tmp_number(fmod (x1, x2)); #else (void) modf(x1 / x2, &x); return tmp_number(x1 - x * x2); #endif case Node_plus: return tmp_number(x1 + x2); case Node_minus: return tmp_number(x1 - x2); case Node_var_array: fatal("attempt to use an array in a scalar context"); default: fatal("illegal type (%d) in tree_eval", tree->type); } return 0; } /* Is TREE true or false? Returns 0==false, non-zero==true */ static int eval_condition(tree) register NODE *tree; { register NODE *t1; register int ret; if (tree == NULL) /* Null trees are the easiest kinds */ return 1; if (tree->type == Node_line_range) { /* * Node_line_range is kind of like Node_match, EXCEPT: the * lnode field (more properly, the condpair field) is a node * of a Node_cond_pair; whether we evaluate the lnode of that * node or the rnode depends on the triggered word. More * precisely: if we are not yet triggered, we tree_eval the * lnode; if that returns true, we set the triggered word. * If we are triggered (not ELSE IF, note), we tree_eval the * rnode, clear triggered if it succeeds, and perform our * action (regardless of success or failure). We want to be * able to begin and end on a single input record, so this * isn't an ELSE IF, as noted above. */ if (!tree->triggered) if (!eval_condition(tree->condpair->lnode)) return 0; else tree->triggered = 1; /* Else we are triggered */ if (eval_condition(tree->condpair->rnode)) tree->triggered = 0; return 1; } /* * Could just be J.random expression. in which case, null and 0 are * false, anything else is true */ t1 = tree_eval(tree); if (t1->flags & MAYBE_NUM) (void) force_number(t1); if (t1->flags & NUMBER) ret = t1->numbr != 0.0; else ret = t1->stlen != 0; free_temp(t1); return ret; } /* * compare two nodes, returning negative, 0, positive */ int cmp_nodes(t1, t2) register NODE *t1, *t2; { register int ret; register int len1, len2; if (t1 == t2) return 0; if (t1->flags & MAYBE_NUM) (void) force_number(t1); if (t2->flags & MAYBE_NUM) (void) force_number(t2); if ((t1->flags & NUMBER) && (t2->flags & NUMBER)) { if (t1->numbr == t2->numbr) return 0; else if (t1->numbr - t2->numbr < 0) return -1; else return 1; } (void) force_string(t1); (void) force_string(t2); len1 = t1->stlen; len2 = t2->stlen; if (len1 == 0 || len2 == 0) return len1 - len2; ret = memcmp(t1->stptr, t2->stptr, len1 <= len2 ? len1 : len2); return ret == 0 ? len1-len2 : ret; } static NODE * op_assign(tree) register NODE *tree; { AWKNUM rval, lval; NODE **lhs; AWKNUM t1, t2; long ltemp; NODE *tmp; Func_ptr after_assign = NULL; lhs = get_lhs(tree->lnode, &after_assign); lval = force_number(*lhs); /* * Can't unref *lhs until we know the type; doing so * too early breaks x += x sorts of things. */ switch(tree->type) { case Node_preincrement: case Node_predecrement: unref(*lhs); *lhs = make_number(lval + (tree->type == Node_preincrement ? 1.0 : -1.0)); if (after_assign) (*after_assign)(); return *lhs; case Node_postincrement: case Node_postdecrement: unref(*lhs); *lhs = make_number(lval + (tree->type == Node_postincrement ? 1.0 : -1.0)); if (after_assign) (*after_assign)(); return tmp_number(lval); default: break; /* handled below */ } tmp = tree_eval(tree->rnode); rval = force_number(tmp); free_temp(tmp); unref(*lhs); switch(tree->type) { case Node_assign_exp: if ((ltemp = rval) == rval) { /* integer exponent */ if (ltemp == 0) *lhs = make_number((AWKNUM) 1); else if (ltemp == 1) *lhs = make_number(lval); else { /* doing it this way should be more precise */ for (t1 = t2 = lval; --ltemp; ) t1 *= t2; *lhs = make_number(t1); } } else *lhs = make_number((AWKNUM) pow((double) lval, (double) rval)); break; case Node_assign_times: *lhs = make_number(lval * rval); break; case Node_assign_quotient: if (rval == (AWKNUM) 0) fatal("division by zero attempted in /="); #ifdef _CRAY /* * special case for integer division, put in for Cray */ ltemp = rval; if (ltemp == 0) { *lhs = make_number(lval / rval); break; } ltemp = (long) lval / ltemp; if (ltemp * lval == rval) *lhs = make_number((AWKNUM) ltemp); else #endif *lhs = make_number(lval / rval); break; case Node_assign_mod: if (rval == (AWKNUM) 0) fatal("division by zero attempted in %="); #ifndef FMOD_MISSING *lhs = make_number(fmod(lval, rval)); #else (void) modf(lval / rval, &t1); t2 = lval - rval * t1; *lhs = make_number(t2); #endif break; case Node_assign_plus: *lhs = make_number(lval + rval); break; case Node_assign_minus: *lhs = make_number(lval - rval); break; default: cant_happen(); } if (after_assign) (*after_assign)(); return *lhs; } NODE **stack_ptr; static NODE * func_call(name, arg_list) NODE *name; /* name is a Node_val giving function name */ NODE *arg_list; /* Node_expression_list of calling args. */ { register NODE *arg, *argp, *r; NODE *n, *f; jmp_buf volatile func_tag_stack; jmp_buf volatile loop_tag_stack; int volatile save_loop_tag_valid = 0; NODE **volatile save_stack, *save_ret_node; NODE **volatile local_stack = NULL, **sp; int count; extern NODE *ret_node; /* * retrieve function definition node */ f = lookup(name->stptr); if (!f || f->type != Node_func) fatal("function `%s' not defined", name->stptr); #ifdef FUNC_TRACE fprintf(stderr, "function %s called\n", name->stptr); #endif count = f->lnode->param_cnt; if (count) emalloc(local_stack, NODE **, count*sizeof(NODE *), "func_call"); sp = local_stack; /* * for each calling arg. add NODE * on stack */ for (argp = arg_list; count && argp != NULL; argp = argp->rnode) { arg = argp->lnode; getnode(r); r->type = Node_var; /* * call by reference for arrays; see below also */ if (arg->type == Node_param_list) arg = stack_ptr[arg->param_cnt]; if (arg->type == Node_var_array) *r = *arg; else { n = tree_eval(arg); r->lnode = dupnode(n); r->rnode = (NODE *) NULL; free_temp(n); } *sp++ = r; count--; } if (argp != NULL) /* left over calling args. */ warning( "function `%s' called with more arguments than declared", name->stptr); /* * add remaining params. on stack with null value */ while (count-- > 0) { getnode(r); r->type = Node_var; r->lnode = Nnull_string; r->rnode = (NODE *) NULL; *sp++ = r; } /* * Execute function body, saving context, as a return statement * will longjmp back here. * * Have to save and restore the loop_tag stuff so that a return * inside a loop in a function body doesn't scrog any loops going * on in the main program. We save the necessary info in variables * local to this function so that function nesting works OK. * We also only bother to save the loop stuff if we're in a loop * when the function is called. */ if (loop_tag_valid) { int junk = 0; save_loop_tag_valid = (volatile int) loop_tag_valid; PUSH_BINDING(loop_tag_stack, loop_tag, junk); loop_tag_valid = 0; } save_stack = stack_ptr; stack_ptr = local_stack; PUSH_BINDING(func_tag_stack, func_tag, func_tag_valid); save_ret_node = ret_node; ret_node = Nnull_string; /* default return value */ if (setjmp(func_tag) == 0) (void) interpret(f->rnode); r = ret_node; ret_node = (NODE *) save_ret_node; RESTORE_BINDING(func_tag_stack, func_tag, func_tag_valid); stack_ptr = (NODE **) save_stack; /* * here, we pop each parameter and check whether * it was an array. If so, and if the arg. passed in was * a simple variable, then the value should be copied back. * This achieves "call-by-reference" for arrays. */ sp = local_stack; count = f->lnode->param_cnt; for (argp = arg_list; count > 0 && argp != NULL; argp = argp->rnode) { arg = argp->lnode; if (arg->type == Node_param_list) arg = stack_ptr[arg->param_cnt]; n = *sp++; if (arg->type == Node_var && n->type == Node_var_array) { /* should we free arg->var_value ? */ arg->var_array = n->var_array; arg->type = Node_var_array; } unref(n->lnode); freenode(n); count--; } while (count-- > 0) { n = *sp++; /* if n is an (local) array, all the elements should be freed */ if (n->type == Node_var_array) { assoc_clear(n); free(n->var_array); } unref(n->lnode); freenode(n); } if (local_stack) free((char *) local_stack); /* Restore the loop_tag stuff if necessary. */ if (save_loop_tag_valid) { int junk = 0; loop_tag_valid = (int) save_loop_tag_valid; RESTORE_BINDING(loop_tag_stack, loop_tag, junk); } if (!(r->flags & PERM)) r->flags |= TEMP; return r; } /* * This returns a POINTER to a node pointer. get_lhs(ptr) is the current * value of the var, or where to store the var's new value */ NODE ** get_lhs(ptr, assign) register NODE *ptr; Func_ptr *assign; { register NODE **aptr = NULL; register NODE *n; switch (ptr->type) { case Node_var_array: fatal("attempt to use an array in a scalar context"); case Node_var: aptr = &(ptr->var_value); #ifdef DEBUG if (ptr->var_value->stref <= 0) cant_happen(); #endif break; case Node_FIELDWIDTHS: aptr = &(FIELDWIDTHS_node->var_value); if (assign) *assign = set_FIELDWIDTHS; break; case Node_RS: aptr = &(RS_node->var_value); if (assign) *assign = set_RS; break; case Node_FS: aptr = &(FS_node->var_value); if (assign) *assign = set_FS; break; case Node_FNR: unref(FNR_node->var_value); FNR_node->var_value = make_number((AWKNUM) FNR); aptr = &(FNR_node->var_value); if (assign) *assign = set_FNR; break; case Node_NR: unref(NR_node->var_value); NR_node->var_value = make_number((AWKNUM) NR); aptr = &(NR_node->var_value); if (assign) *assign = set_NR; break; case Node_NF: if (NF == -1) (void) get_field(HUGE-1, assign); /* parse record */ unref(NF_node->var_value); NF_node->var_value = make_number((AWKNUM) NF); aptr = &(NF_node->var_value); if (assign) *assign = set_NF; break; case Node_IGNORECASE: unref(IGNORECASE_node->var_value); IGNORECASE_node->var_value = make_number((AWKNUM) IGNORECASE); aptr = &(IGNORECASE_node->var_value); if (assign) *assign = set_IGNORECASE; break; case Node_OFMT: aptr = &(OFMT_node->var_value); if (assign) *assign = set_OFMT; break; case Node_CONVFMT: aptr = &(CONVFMT_node->var_value); if (assign) *assign = set_CONVFMT; break; case Node_ORS: aptr = &(ORS_node->var_value); if (assign) *assign = set_ORS; break; case Node_OFS: aptr = &(OFS_node->var_value); if (assign) *assign = set_OFS; break; case Node_param_list: aptr = &(stack_ptr[ptr->param_cnt]->var_value); break; case Node_field_spec: { int field_num; n = tree_eval(ptr->lnode); field_num = (int) force_number(n); free_temp(n); if (field_num < 0) fatal("attempt to access field %d", field_num); if (field_num == 0 && field0_valid) { /* short circuit */ aptr = &fields_arr[0]; if (assign) *assign = reset_record; break; } aptr = get_field(field_num, assign); break; } case Node_subscript: n = ptr->lnode; if (n->type == Node_param_list) n = stack_ptr[n->param_cnt]; aptr = assoc_lookup(n, concat_exp(ptr->rnode)); break; case Node_func: fatal ("`%s' is a function, assignment is not allowed", ptr->lnode->param); default: cant_happen(); } return aptr; } static NODE * match_op(tree) register NODE *tree; { register NODE *t1; register Regexp *rp; int i; int match = 1; if (tree->type == Node_nomatch) match = 0; if (tree->type == Node_regex) t1 = *get_field(0, (Func_ptr *) 0); else { t1 = force_string(tree_eval(tree->lnode)); tree = tree->rnode; } rp = re_update(tree); i = research(rp, t1->stptr, 0, t1->stlen, 0); i = (i == -1) ^ (match == 1); free_temp(t1); return tmp_number((AWKNUM) i); } void set_IGNORECASE() { static int warned = 0; if ((do_lint || do_unix) && ! warned) { warned = 1; warning("IGNORECASE not supported in compatibility mode"); } IGNORECASE = (force_number(IGNORECASE_node->var_value) != 0.0); set_FS(); } void set_OFS() { OFS = force_string(OFS_node->var_value)->stptr; OFSlen = OFS_node->var_value->stlen; OFS[OFSlen] = '\0'; } void set_ORS() { ORS = force_string(ORS_node->var_value)->stptr; ORSlen = ORS_node->var_value->stlen; ORS[ORSlen] = '\0'; } static NODE **fmt_list = NULL; static int fmt_ok P((NODE *n)); static int fmt_index P((NODE *n)); static int fmt_ok(n) NODE *n; { /* to be done later */ return 1; } static int fmt_index(n) NODE *n; { register int ix = 0; static int fmt_num = 4; static int fmt_hiwater = 0; if (fmt_list == NULL) emalloc(fmt_list, NODE **, fmt_num*sizeof(*fmt_list), "fmt_index"); (void) force_string(n); while (ix < fmt_hiwater) { if (cmp_nodes(fmt_list[ix], n) == 0) return ix; ix++; } /* not found */ n->stptr[n->stlen] = '\0'; if (!fmt_ok(n)) warning("bad FMT specification"); if (fmt_hiwater >= fmt_num) { fmt_num *= 2; emalloc(fmt_list, NODE **, fmt_num, "fmt_index"); } fmt_list[fmt_hiwater] = dupnode(n); return fmt_hiwater++; } void set_OFMT() { OFMTidx = fmt_index(OFMT_node->var_value); OFMT = fmt_list[OFMTidx]->stptr; } void set_CONVFMT() { CONVFMTidx = fmt_index(CONVFMT_node->var_value); CONVFMT = fmt_list[CONVFMTidx]->stptr; }