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view lwlib/lw_expr.c @ 236:ce1fdc8d6568
Added ability to add padding after a section when linking.
Added the ability for lwlink to automatically append padding bytes to the
end of a section (once the section instances are merged). This behaviour is
controlled by the link script. See the updated documentation for more
information.
author | William Astle <lost@l-w.ca> |
---|---|
date | Sat, 11 Aug 2012 23:29:57 -0600 |
parents | 348e2816ce32 |
children | 1f1a28b797e1 |
line wrap: on
line source
/* lwexpr.c Copyright © 2010 William Astle This file is part of LWTOOLS. LWTOOLS 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 3 of the License, or (at your option) any later version. This program 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 this program. If not, see <http://www.gnu.org/licenses/>. */ #include <stdarg.h> #include <stdio.h> #include <string.h> #include <ctype.h> #define ___lw_expr_c_seen___ #include "lw_alloc.h" #include "lw_expr.h" #include "lw_error.h" #include "lw_string.h" static lw_expr_fn_t *evaluate_special = NULL; static lw_expr_fn2_t *evaluate_var = NULL; static lw_expr_fn3_t *parse_term = NULL; /* Q&D to break out of infinite recursion */ static int level = 0; static int bailing = 0; int lw_expr_istype(lw_expr_t e, int t) { /* NULL expression is never of any type */ if (!e) return 0; if (e -> type == t) return 1; return 0; } int lw_expr_intval(lw_expr_t e) { if (e -> type == lw_expr_type_int) return e -> value; return -1; } int lw_expr_whichop(lw_expr_t e) { if (e -> type == lw_expr_type_oper) return e -> value; return -1; } int lw_expr_specint(lw_expr_t e) { if (e -> type == lw_expr_type_special) return e -> value; return -1; } void lw_expr_set_term_parser(lw_expr_fn3_t *fn) { parse_term = fn; } void lw_expr_set_special_handler(lw_expr_fn_t *fn) { evaluate_special = fn; } void lw_expr_set_var_handler(lw_expr_fn2_t *fn) { evaluate_var = fn; } lw_expr_t lw_expr_create(void) { lw_expr_t r; r = lw_alloc(sizeof(struct lw_expr_priv)); r -> operands = NULL; r -> value2 = NULL; r -> type = lw_expr_type_int; r -> value = 0; return r; } void lw_expr_destroy(lw_expr_t E) { struct lw_expr_opers *o; if (!E) return; while (E -> operands) { o = E -> operands; E -> operands = o -> next; lw_expr_destroy(o -> p); lw_free(o); } if (E -> type == lw_expr_type_var) lw_free(E -> value2); lw_free(E); } /* actually duplicates the entire expression */ void lw_expr_add_operand(lw_expr_t E, lw_expr_t O); lw_expr_t lw_expr_copy(lw_expr_t E) { lw_expr_t r; struct lw_expr_opers *o; if (!E) return NULL; r = lw_alloc(sizeof(struct lw_expr_priv)); *r = *E; r -> operands = NULL; if (E -> type == lw_expr_type_var) r -> value2 = lw_strdup(E -> value2); for (o = E -> operands; o; o = o -> next) { lw_expr_add_operand(r, o -> p); } return r; } void lw_expr_add_operand(lw_expr_t E, lw_expr_t O) { struct lw_expr_opers *o, *t; o = lw_alloc(sizeof(struct lw_expr_opers)); o -> p = lw_expr_copy(O); o -> next = NULL; for (t = E -> operands; t && t -> next; t = t -> next) /* do nothing */ ; if (t) t -> next = o; else E -> operands = o; } lw_expr_t lw_expr_build_aux(int exprtype, va_list args) { lw_expr_t r; int t; void *p; lw_expr_t te1, te2; r = lw_expr_create(); switch (exprtype) { case lw_expr_type_int: t = va_arg(args, int); r -> type = lw_expr_type_int; r -> value = t; break; case lw_expr_type_var: p = va_arg(args, char *); r -> type = lw_expr_type_var; r -> value2 = lw_strdup(p); break; case lw_expr_type_special: t = va_arg(args, int); p = va_arg(args, char *); r -> type = lw_expr_type_special; r -> value = t; r -> value2 = p; break; case lw_expr_type_oper: t = va_arg(args, int); te1 = va_arg(args, lw_expr_t); if (t != lw_expr_oper_com && t != lw_expr_oper_neg) te2 = va_arg(args, lw_expr_t); else te2 = NULL; r -> type = lw_expr_type_oper; r -> value = t; lw_expr_add_operand(r, te1); if (te2) lw_expr_add_operand(r, te2); break; default: lw_error("Invalid expression type specified to lw_expr_build"); } return r; } lw_expr_t lw_expr_build(int exprtype, ...) { va_list args; lw_expr_t r; va_start(args, exprtype); r = lw_expr_build_aux(exprtype, args); va_end(args); return r; } void lw_expr_print_aux(lw_expr_t E, char **obuf, int *buflen, int *bufloc) { struct lw_expr_opers *o; int c = 0; char buf[256]; if (!E) { strcpy(buf, "(NULL)"); return; } for (o = E -> operands; o; o = o -> next) { c++; lw_expr_print_aux(o -> p, obuf, buflen, bufloc); } switch (E -> type) { case lw_expr_type_int: if (E -> value < 0) snprintf(buf, 256, "-%#x ", -(E -> value)); else snprintf(buf, 256, "%#x ", E -> value); break; case lw_expr_type_var: snprintf(buf, 256, "V(%s) ", (char *)(E -> value2)); break; case lw_expr_type_special: snprintf(buf, 256, "S(%d,%p) ", E -> value, E -> value2); break; case lw_expr_type_oper: snprintf(buf, 256, "[%d]", c); switch (E -> value) { case lw_expr_oper_plus: strcat(buf, "+ "); break; case lw_expr_oper_minus: strcat(buf, "- "); break; case lw_expr_oper_times: strcat(buf, "* "); break; case lw_expr_oper_divide: strcat(buf, "/ "); break; case lw_expr_oper_mod: strcat(buf, "% "); break; case lw_expr_oper_intdiv: strcat(buf, "\\ "); break; case lw_expr_oper_bwand: strcat(buf, "BWAND "); break; case lw_expr_oper_bwor: strcat(buf, "BWOR "); break; case lw_expr_oper_bwxor: strcat(buf, "BWXOR "); break; case lw_expr_oper_and: strcat(buf, "AND "); break; case lw_expr_oper_or: strcat(buf, "OR "); break; case lw_expr_oper_neg: strcat(buf, "NEG "); break; case lw_expr_oper_com: strcat(buf, "COM "); break; default: strcat(buf, "OPER "); break; } break; default: snprintf(buf, 256, "ERR "); break; } c = strlen(buf); if (*bufloc + c >= *buflen) { *buflen += 128; *obuf = lw_realloc(*obuf, *buflen); } strcpy(*obuf + *bufloc, buf); *bufloc += c; } char *lw_expr_print(lw_expr_t E) { static char *obuf = NULL; static int obufsize = 0; int obufloc = 0; lw_expr_print_aux(E, &obuf, &obufsize, &obufloc); return obuf; } /* Return: nonzero if expressions are the same (identical pointers or matching values) zero if expressions are not the same */ int lw_expr_compare(lw_expr_t E1, lw_expr_t E2) { struct lw_expr_opers *o1, *o2; if (E1 == E2) return 1; if (!E1 || !E2) return 0; if (!(E1 -> type == E2 -> type && E1 -> value == E2 -> value)) return 0; if (E1 -> type == lw_expr_type_var) { if (!strcmp(E1 -> value2, E2 -> value2)) return 1; else return 0; } if (E1 -> type == lw_expr_type_special) { if (E1 -> value2 == E2 -> value2) return 1; else return 0; } for (o1 = E1 -> operands, o2 = E2 -> operands; o1 && o2; o1 = o1 -> next, o2 = o2 -> next) if (lw_expr_compare(o1 -> p, o2 -> p) == 0) return 0; if (o1 || o2) return 0; return 1; } /* return true if E is an operator of type oper */ int lw_expr_isoper(lw_expr_t E, int oper) { if (E -> type == lw_expr_type_oper && E -> value == oper) return 1; return 0; } void lw_expr_simplify_sortconstfirst(lw_expr_t E) { struct lw_expr_opers *o; if (E -> type != lw_expr_type_oper) return; if (E -> value != lw_expr_oper_times && E -> value != lw_expr_oper_plus) return; for (o = E -> operands; o; o = o -> next) { if (o -> p -> type == lw_expr_type_oper && (o -> p -> value == lw_expr_oper_times || o -> p -> value == lw_expr_oper_plus)) lw_expr_simplify_sortconstfirst(o -> p); } for (o = E -> operands; o; o = o -> next) { if (o -> p -> type == lw_expr_type_int && o != E -> operands) { struct lw_expr_opers *o2; for (o2 = E -> operands; o2 -> next != o; o2 = o2 -> next) /* do nothing */ ; o2 -> next = o -> next; o -> next = E -> operands; E -> operands = o; o = o2; } } } void lw_expr_sortoperandlist(struct lw_expr_opers **o) { // fprintf(stderr, "lw_expr_sortoperandlist() not yet implemented\n"); } // return 1 if the operand lists match, 0 if not // may re-order the argument lists int lw_expr_simplify_compareoperandlist(struct lw_expr_opers **ol1, struct lw_expr_opers **ol2) { struct lw_expr_opers *o1, *o2; lw_expr_sortoperandlist(ol1); lw_expr_sortoperandlist(ol2); for (o1 = *ol1, o2 = *ol2; o1 && o2; o1 = o1 -> next, o2 = o2 -> next) { if (!lw_expr_compare(o1 -> p, o2 -> p)) return 0; } if (o1 || o2) return 0; return 1; } int lw_expr_simplify_isliketerm(lw_expr_t e1, lw_expr_t e2) { // first term is a "times" if (e1 -> type == lw_expr_type_oper && e1 -> value == lw_expr_oper_times) { // second term is a "times" if (e2 -> type == lw_expr_type_oper && e2 -> value == lw_expr_oper_times) { // both times - easy check struct lw_expr_opers *o1, *o2; for (o1 = e1 -> operands; o1; o1 = o1 -> next) if (o1 -> p -> type != lw_expr_type_int) break; for (o2 = e2 -> operands; o2; o2 = o2 -> next) if (o2 -> p -> type != lw_expr_type_int) break; if (lw_expr_simplify_compareoperandlist(&o1, &o2)) return 1; return 0; } // not a times - have to assume it's the operand list // with a "1 *" in front if it if (!e1 -> operands -> next) return 0; if (e1 -> operands -> next -> next) return 0; if (!lw_expr_compare(e1 -> operands -> next -> p, e2)) return 0; return 1; } // e1 is not a times if (e2 -> type == lw_expr_type_oper && e2 -> value == lw_expr_oper_times) { // e2 is a times if (e2 -> operands -> next -> next) return 0; if (!lw_expr_compare(e1, e2 -> operands -> next -> p)) return 0; return 1; } // neither are times if (!lw_expr_compare(e1, e2)) return 0; return 1; } int lw_expr_contains(lw_expr_t E, lw_expr_t E1) { struct lw_expr_opers *o; // NULL expr contains nothing :) if (!E) return 0; if (E1 -> type != lw_expr_type_var && E1 -> type != lw_expr_type_special) return 0; if (lw_expr_compare(E, E1)) return 1; for (o = E -> operands; o; o = o -> next) { if (lw_expr_contains(o -> p, E1)) return 1; } return 0; } void lw_expr_simplify_l(lw_expr_t E, void *priv); void lw_expr_simplify_go(lw_expr_t E, void *priv) { struct lw_expr_opers *o; // replace subtraction with O1 + -1(O2)... // needed for like term collection if (E -> type == lw_expr_type_oper && E -> value == lw_expr_oper_minus) { for (o = E -> operands -> next; o; o = o -> next) { lw_expr_t e1, e2; e2 = lw_expr_build(lw_expr_type_int, -1); e1 = lw_expr_build(lw_expr_type_oper, lw_expr_oper_times, e2, o -> p); lw_expr_destroy(o -> p); lw_expr_destroy(e2); o -> p = e1; } E -> value = lw_expr_oper_plus; } // turn "NEG" into -1(O) - needed for like term collection if (E -> type == lw_expr_type_oper && E -> value == lw_expr_oper_neg) { lw_expr_t e1; E -> value = lw_expr_oper_times; e1 = lw_expr_build(lw_expr_type_int, -1); lw_expr_add_operand(E, e1); lw_expr_destroy(e1); } again: // try to resolve non-constant terms to constants here if (E -> type == lw_expr_type_special && evaluate_special) { lw_expr_t te; te = evaluate_special(E -> value, E -> value2, priv); if (lw_expr_contains(te, E)) lw_expr_destroy(te); if (te) { for (o = E -> operands; o; o = o -> next) lw_expr_destroy(o -> p); if (E -> type == lw_expr_type_var) lw_free(E -> value2); *E = *te; E -> operands = NULL; if (te -> type == lw_expr_type_var) E -> value2 = lw_strdup(te -> value2); for (o = te -> operands; o; o = o -> next) { lw_expr_t xxx; xxx = lw_expr_copy(o -> p); lw_expr_add_operand(E, xxx); lw_expr_destroy(xxx); } lw_expr_destroy(te); goto again; } return; } if (E -> type == lw_expr_type_var && evaluate_var) { lw_expr_t te; te = evaluate_var(E -> value2, priv); if (lw_expr_contains(te, E)) lw_expr_destroy(te); else if (te) { for (o = E -> operands; o; o = o -> next) lw_expr_destroy(o -> p); if (E -> type == lw_expr_type_var) lw_free(E -> value2); *E = *te; E -> operands = NULL; if (te -> type == lw_expr_type_var) E -> value2 = lw_strdup(te -> value2); for (o = te -> operands; o; o = o -> next) { lw_expr_add_operand(E, lw_expr_copy(o -> p)); } lw_expr_destroy(te); goto again; } return; } // non-operators have no simplification to do! if (E -> type != lw_expr_type_oper) return; // merge plus operations if (E -> value == lw_expr_oper_plus) { tryagainplus: for (o = E -> operands; o; o = o -> next) { if (o -> p -> type == lw_expr_type_oper && o -> p -> value == lw_expr_oper_plus) { struct lw_expr_opers *o2; // we have a + operation - bring operands up for (o2 = E -> operands; o2 && o2 -> next != o; o2 = o2 -> next) /* do nothing */ ; if (o2) o2 -> next = o -> p -> operands; else E -> operands = o -> p -> operands; for (o2 = o -> p -> operands; o2 -> next; o2 = o2 -> next) /* do nothing */ ; o2 -> next = o -> next; o -> p -> operands = NULL; lw_expr_destroy(o -> p); lw_free(o); goto tryagainplus; } } } // merge times operations if (E -> value == lw_expr_oper_times) { tryagaintimes: for (o = E -> operands; o; o = o -> next) { if (o -> p -> type == lw_expr_type_oper && o -> p -> value == lw_expr_oper_times) { struct lw_expr_opers *o2; // we have a + operation - bring operands up for (o2 = E -> operands; o2 && o2 -> next != o; o2 = o2 -> next) /* do nothing */ ; if (o2) o2 -> next = o -> p -> operands; else E -> operands = o -> p -> operands; for (o2 = o -> p -> operands; o2 -> next; o2 = o2 -> next) /* do nothing */ ; o2 -> next = o -> next; o -> p -> operands = NULL; lw_expr_destroy(o -> p); lw_free(o); goto tryagaintimes; } } } // simplify operands for (o = E -> operands; o; o = o -> next) if (o -> p -> type != lw_expr_type_int) lw_expr_simplify_l(o -> p, priv); for (o = E -> operands; o; o = o -> next) { if (o -> p -> type != lw_expr_type_int) break; } if (!o) { // we can do the operation here! int tr = -42424242; switch (E -> value) { case lw_expr_oper_neg: tr = -(E -> operands -> p -> value); break; case lw_expr_oper_com: tr = ~(E -> operands -> p -> value); break; case lw_expr_oper_plus: tr = E -> operands -> p -> value; for (o = E -> operands -> next; o; o = o -> next) tr += o -> p -> value; break; case lw_expr_oper_minus: tr = E -> operands -> p -> value; for (o = E -> operands -> next; o; o = o -> next) tr -= o -> p -> value; break; case lw_expr_oper_times: tr = E -> operands -> p -> value; for (o = E -> operands -> next; o; o = o -> next) tr *= o -> p -> value; break; case lw_expr_oper_divide: tr = E -> operands -> p -> value / E -> operands -> next -> p -> value; break; case lw_expr_oper_mod: tr = E -> operands -> p -> value % E -> operands -> next -> p -> value; break; case lw_expr_oper_intdiv: tr = E -> operands -> p -> value / E -> operands -> next -> p -> value; break; case lw_expr_oper_bwand: tr = E -> operands -> p -> value & E -> operands -> next -> p -> value; break; case lw_expr_oper_bwor: tr = E -> operands -> p -> value | E -> operands -> next -> p -> value; break; case lw_expr_oper_bwxor: tr = E -> operands -> p -> value ^ E -> operands -> next -> p -> value; break; case lw_expr_oper_and: tr = E -> operands -> p -> value && E -> operands -> next -> p -> value; break; case lw_expr_oper_or: tr = E -> operands -> p -> value || E -> operands -> next -> p -> value; break; } while (E -> operands) { o = E -> operands; E -> operands = o -> next; lw_expr_destroy(o -> p); lw_free(o); } E -> type = lw_expr_type_int; E -> value = tr; return; } if (E -> value == lw_expr_oper_plus) { lw_expr_t e1; int cval = 0; e1 = lw_expr_create(); e1 -> operands = E -> operands; E -> operands = 0; for (o = e1 -> operands; o; o = o -> next) { if (o -> p -> type == lw_expr_type_int) cval += o -> p -> value; else lw_expr_add_operand(E, o -> p); } lw_expr_destroy(e1); if (cval) { e1 = lw_expr_build(lw_expr_type_int, cval); lw_expr_add_operand(E, e1); lw_expr_destroy(e1); } } if (E -> value == lw_expr_oper_times) { lw_expr_t e1; int cval = 1; e1 = lw_expr_create(); e1 -> operands = E -> operands; E -> operands = 0; for (o = e1 -> operands; o; o = o -> next) { if (o -> p -> type == lw_expr_type_int) cval *= o -> p -> value; else lw_expr_add_operand(E, o -> p); } lw_expr_destroy(e1); if (cval != 1) { e1 = lw_expr_build(lw_expr_type_int, cval); lw_expr_add_operand(E, e1); lw_expr_destroy(e1); } } if (E -> value == lw_expr_oper_times) { for (o = E -> operands; o; o = o -> next) { if (o -> p -> type == lw_expr_type_int && o -> p -> value == 0) { // one operand of times is 0, replace operation with 0 while (E -> operands) { o = E -> operands; E -> operands = o -> next; lw_expr_destroy(o -> p); lw_free(o); } E -> type = lw_expr_type_int; E -> value = 0; return; } } } // sort "constants" to the start of each operand list for + and * if (E -> value == lw_expr_oper_plus || E -> value == lw_expr_oper_times) lw_expr_simplify_sortconstfirst(E); // look for like terms and collect them together if (E -> value == lw_expr_oper_plus) { struct lw_expr_opers *o2; for (o = E -> operands; o; o = o -> next) { // skip constants if (o -> p -> type == lw_expr_type_int) continue; // we have a term to match // (o -> p) is first term for (o2 = o -> next; o2; o2 = o2 -> next) { lw_expr_t e1, e2; if (o2 -> p -> type == lw_expr_type_int) continue; if (lw_expr_simplify_isliketerm(o -> p, o2 -> p)) { int coef, coef2; // we have a like term here // do something about it if (o -> p -> type == lw_expr_type_oper && o -> p -> value == lw_expr_oper_times) { if (o -> p -> operands -> p -> type == lw_expr_type_int) coef = o -> p -> operands -> p -> value; else coef = 1; } else coef = 1; if (o2 -> p -> type == lw_expr_type_oper && o2 -> p -> value == lw_expr_oper_times) { if (o2 -> p -> operands -> p -> type == lw_expr_type_int) coef2 = o2 -> p -> operands -> p -> value; else coef2 = 1; } else coef2 = 1; coef += coef2; e1 = lw_expr_create(); e1 -> type = lw_expr_type_oper; e1 -> value = lw_expr_oper_times; if (coef != 1) { e2 = lw_expr_build(lw_expr_type_int, coef); lw_expr_add_operand(e1, e2); lw_expr_destroy(e2); } lw_expr_destroy(o -> p); o -> p = e1; for (o = o2 -> p -> operands; o; o = o -> next) { if (o -> p -> type == lw_expr_type_int) continue; lw_expr_add_operand(e1, o -> p); } lw_expr_destroy(o2 -> p); o2 -> p = lw_expr_build(lw_expr_type_int, 0); goto again; } } } } if (E -> value == lw_expr_oper_plus) { int c = 0, t = 0; for (o = E -> operands; o; o = o -> next) { t++; if (!(o -> p -> type == lw_expr_type_int && o -> p -> value == 0)) { c++; } } if (c == 1) { lw_expr_t r; // find the value and "move it up" while (E -> operands) { o = E -> operands; if (o -> p -> type != lw_expr_type_int || o -> p -> value != 0) { r = lw_expr_copy(o -> p); } E -> operands = o -> next; lw_expr_destroy(o -> p); lw_free(o); } *E = *r; lw_free(r); return; } else if (c == 0) { // replace with 0 while (E -> operands) { o = E -> operands; E -> operands = o -> next; lw_expr_destroy(o -> p); lw_free(o); } E -> type = lw_expr_type_int; E -> value = 0; return; } else if (c != t) { // collapse out zero terms struct lw_expr_opers *o2; for (o = E -> operands; o; o = o -> next) { if (o -> p -> type == lw_expr_type_int && o -> p -> value == 0) { if (o == E -> operands) { E -> operands = o -> next; lw_expr_destroy(o -> p); lw_free(o); o = E -> operands; } else { for (o2 = E -> operands; o2 -> next == o; o2 = o2 -> next) /* do nothing */ ; o2 -> next = o -> next; lw_expr_destroy(o -> p); lw_free(o); o = o2; } } } } return; } /* handle <int> times <plus> - expand the terms - only with exactly two operands */ if (E -> value == lw_expr_oper_times) { lw_expr_t t1; lw_expr_t E2; lw_expr_t E3; if (E -> operands && E -> operands -> next && !(E -> operands -> next -> next)) { if (E -> operands -> p -> type == lw_expr_type_int) { /* <int> TIMES <other> */ E2 = E -> operands -> next -> p; E3 = E -> operands -> p; if (E2 -> type == lw_expr_type_oper && E2 -> value == lw_expr_oper_plus) { lw_free(E -> operands -> next); lw_free(E -> operands); E -> operands = NULL; E -> value = lw_expr_oper_plus; for (o = E2 -> operands; o; o = o -> next) { t1 = lw_expr_build(lw_expr_type_oper, lw_expr_oper_times, E3, o -> p); lw_expr_add_operand(E, t1); lw_expr_destroy(t1); } lw_expr_destroy(E2); lw_expr_destroy(E3); } } else if (E -> operands -> next -> p -> type == lw_expr_type_int) { /* <other> TIMES <int> */ E2 = E -> operands -> p; E3 = E -> operands -> next -> p; if (E2 -> type == lw_expr_type_oper && E2 -> value == lw_expr_oper_plus) { lw_free(E -> operands -> next); lw_free(E -> operands); E -> operands = NULL; E -> value = lw_expr_oper_plus; for (o = E2 -> operands; o; o = o -> next) { t1 = lw_expr_build(lw_expr_type_oper, lw_expr_oper_times, E3, o -> p); lw_expr_add_operand(E, t1); } lw_expr_destroy(E2); lw_expr_destroy(E3); } } } } } void lw_expr_simplify_l(lw_expr_t E, void *priv) { lw_expr_t te; int c; (level)++; // bail out if the level gets too deep if (level >= 500 || bailing) { bailing = 1; level--; if (level == 0) bailing = 0; return; } do { te = lw_expr_copy(E); lw_expr_simplify_go(E, priv); c = 0; if (lw_expr_compare(te, E) == 0) c = 1; lw_expr_destroy(te); } while (c); (level)--; } void lw_expr_simplify(lw_expr_t E, void *priv) { if (E -> type == lw_expr_type_int) return; lw_expr_simplify_l(E, priv); } /* The following two functions are co-routines which evaluate an infix expression. lw_expr_parse_term checks for unary prefix operators then, if none found, passes the string off the the defined helper function to determine what the term really is. It also handles parentheses. lw_expr_parse_expr evaluates actual expressions with infix operators. It respects the order of operations. The end of an expression is determined by the presence of any of the following conditions: 1. a NUL character 2. a whitespace character 3. a ) 4. a , 5. any character that is not recognized as a term lw_expr_parse_term returns NULL if there is no term (end of expr, etc.) lw_expr_parse_expr returns NULL if there is no expression or on a syntax error. */ lw_expr_t lw_expr_parse_expr(char **p, void *priv, int prec); lw_expr_t lw_expr_parse_term(char **p, void *priv) { lw_expr_t term, term2; eval_next: if (!**p || isspace(**p) || **p == ')' || **p == ']') return NULL; // parentheses if (**p == '(') { (*p)++; term = lw_expr_parse_expr(p, priv, 0); if (**p != ')') { lw_expr_destroy(term); return NULL; } (*p)++; return term; } // unary + if (**p == '+') { (*p)++; goto eval_next; } // unary - (prec 200) if (**p == '-') { (*p)++; term = lw_expr_parse_expr(p, priv, 200); if (!term) return NULL; term2 = lw_expr_build(lw_expr_type_oper, lw_expr_oper_neg, term); lw_expr_destroy(term); return term2; } // unary ^ or ~ (complement, prec 200) if (**p == '^' || **p == '~') { (*p)++; term = lw_expr_parse_expr(p, priv, 200); if (!term) return NULL; term2 = lw_expr_build(lw_expr_type_oper, lw_expr_oper_com, term); lw_expr_destroy(term); return term2; } // non-operator - pass to caller return parse_term(p, priv); } lw_expr_t lw_expr_parse_expr(char **p, void *priv, int prec) { static const struct operinfo { int opernum; char *operstr; int operprec; } operators[] = { { lw_expr_oper_plus, "+", 100 }, { lw_expr_oper_minus, "-", 100 }, { lw_expr_oper_times, "*", 150 }, { lw_expr_oper_divide, "/", 150 }, { lw_expr_oper_mod, "%", 150 }, { lw_expr_oper_intdiv, "\\", 150 }, { lw_expr_oper_and, "&&", 25 }, { lw_expr_oper_or, "||", 25 }, { lw_expr_oper_bwand, "&", 50 }, { lw_expr_oper_bwor, "|", 50 }, { lw_expr_oper_bwor, "!", 50 }, { lw_expr_oper_bwxor, "^", 50 }, { lw_expr_oper_none, "", 0 } }; int opern, i; lw_expr_t term1, term2, term3; if (!**p || isspace(**p) || **p == ')' || **p == ',' || **p == ']') return NULL; term1 = lw_expr_parse_term(p, priv); if (!term1) return NULL; eval_next: if (!**p || isspace(**p) || **p == ')' || **p == ',' || **p == ']') return term1; // expecting an operator here for (opern = 0; operators[opern].opernum != lw_expr_oper_none; opern++) { for (i = 0; (*p)[i] && operators[opern].operstr[i] && ((*p)[i] == operators[opern].operstr[i]); i++) /* do nothing */; if (operators[opern].operstr[i] == '\0') break; } if (operators[opern].opernum == lw_expr_oper_none) { // unrecognized operator lw_expr_destroy(term1); return NULL; } // operator number is in opern, length of oper in i // logic: // if the precedence of this operation is <= to the "prec" flag, // we simply return without advancing the input pointer; the operator // will be evaluated again in the enclosing function call if (operators[opern].operprec <= prec) return term1; // logic: // we have a higher precedence operator here so we will advance the // input pointer to the next term and let the expression evaluator // loose on it after which time we will push our operator onto the // stack and then go on with the expression evaluation (*p) += i; // evaluate next expression(s) of higher precedence term2 = lw_expr_parse_expr(p, priv, operators[opern].operprec); if (!term2) { lw_expr_destroy(term1); return NULL; } // now create operator term3 = lw_expr_build(lw_expr_type_oper, operators[opern].opernum, term1, term2); lw_expr_destroy(term1); lw_expr_destroy(term2); // the new "expression" is the next "left operand" term1 = term3; // continue evaluating goto eval_next; } lw_expr_t lw_expr_parse(char **p, void *priv) { return lw_expr_parse_expr(p, priv, 0); } int lw_expr_testterms(lw_expr_t e, lw_expr_testfn_t *fn, void *priv) { struct lw_expr_opers *o; int r; for (o = e -> operands; o; o = o -> next) { r = lw_expr_testterms(o -> p, fn, priv); if (r) return r; } return (fn)(e, priv); } int lw_expr_type(lw_expr_t e) { return e -> type; } void *lw_expr_specptr(lw_expr_t e) { return e -> value2; } int lw_expr_operandcount(lw_expr_t e) { int count = 0; struct lw_expr_opers *o; if (e -> type != lw_expr_type_oper) return 0; for (o = e -> operands; o; o = o -> next) count++; return count; }