354 lines
8.4 KiB
C
354 lines
8.4 KiB
C
/*
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* (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands.
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* See the copyright notice in the ACK home directory, in the file "Copyright".
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*/
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/* $Header$ */
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/* SEMANTIC ANALYSIS (CHAPTER 3.3) -- BINARY OPERATORS */
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#include "botch_free.h"
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#include <alloc.h>
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#include "lint.h"
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#include "idf.h"
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#include <flt_arith.h>
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#include "arith.h"
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#include "type.h"
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#include "struct.h"
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#include "label.h"
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#include "expr.h"
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#include "Lpars.h"
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extern char options[];
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extern char *symbol2str();
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/* This chapter asks for the repeated application of code to handle
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an operation that may be executed at compile time or at run time,
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depending on the constancy of the operands.
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*/
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#define commutative_binop(expp, oper, expr) mk_binop(expp, oper, expr, 1)
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#define non_commutative_binop(expp, oper, expr) mk_binop(expp, oper, expr, 0)
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ch3bin(expp, oper, expr)
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register struct expr **expp;
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struct expr *expr;
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{
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/* apply binary operator oper between *expp and expr.
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NB: don't swap operands if op is one of the op= operators!!!
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*/
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any2opnd(expp, oper);
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any2opnd(&expr, oper);
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switch (oper) {
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case '[': /* 3.3.2.1 */
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/* indexing follows the commutative laws */
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switch ((*expp)->ex_type->tp_fund) {
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case POINTER:
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case ARRAY:
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break;
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case ERRONEOUS:
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return;
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default: /* unindexable */
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switch (expr->ex_type->tp_fund) {
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case POINTER:
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case ARRAY:
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break;
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case ERRONEOUS:
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return;
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default:
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expr_error(*expp,
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"indexing an object of type %s",
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symbol2str((*expp)->ex_type->tp_fund));
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return;
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}
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break;
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}
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ch3bin(expp, '+', expr);
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ch3mon('*', expp);
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break;
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case '(': /* 3.3.2.2 */
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if ( (*expp)->ex_type->tp_fund == POINTER &&
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(*expp)->ex_type->tp_up->tp_fund == FUNCTION
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) {
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ch3mon('*', expp);
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}
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if ((*expp)->ex_type->tp_fund != FUNCTION) {
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expr_error(*expp, "call of non-function (%s)",
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symbol2str((*expp)->ex_type->tp_fund));
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/* leave the expression; it may still serve */
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free_expression(expr); /* there go the parameters */
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*expp = new_oper(error_type,
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*expp, '(', (struct expr *)0);
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}
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else
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*expp = new_oper((*expp)->ex_type->tp_up,
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*expp, '(', expr);
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(*expp)->ex_flags |= EX_SIDEEFFECTS;
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break;
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case PARCOMMA: /* 3.3.2.2 */
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if ((*expp)->ex_type->tp_fund == FUNCTION)
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function2pointer(*expp);
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*expp = new_oper(expr->ex_type, *expp, PARCOMMA, expr);
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break;
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case '%':
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case MODAB:
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case ANDAB:
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case XORAB:
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case ORAB:
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opnd2integral(expp, oper);
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opnd2integral(&expr, oper);
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/* fallthrough */
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case '/':
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case DIVAB:
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case TIMESAB:
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arithbalance(expp, oper, &expr);
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non_commutative_binop(expp, oper, expr);
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break;
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case '&':
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case '^':
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case '|':
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opnd2integral(expp, oper);
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opnd2integral(&expr, oper);
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/* fallthrough */
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case '*':
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arithbalance(expp, oper, &expr);
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commutative_binop(expp, oper, expr);
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break;
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case '+':
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if (expr->ex_type->tp_fund == POINTER) { /* swap operands */
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struct expr *etmp = expr;
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expr = *expp;
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*expp = etmp;
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}
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/* fallthrough */
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case PLUSAB:
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case POSTINCR:
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case PLUSPLUS:
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if ((*expp)->ex_type->tp_fund == POINTER) {
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pointer_arithmetic(expp, oper, &expr);
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if (expr->ex_type->tp_size != (*expp)->ex_type->tp_size)
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ch3cast(&expr, CAST, (*expp)->ex_type);
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pointer_binary(expp, oper, expr);
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}
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else {
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arithbalance(expp, oper, &expr);
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if (oper == '+')
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commutative_binop(expp, oper, expr);
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else
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non_commutative_binop(expp, oper, expr);
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}
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break;
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case '-':
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case MINAB:
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case POSTDECR:
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case MINMIN:
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if ((*expp)->ex_type->tp_fund == POINTER) {
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if (expr->ex_type->tp_fund == POINTER)
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pntminuspnt(expp, oper, expr);
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else {
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pointer_arithmetic(expp, oper, &expr);
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pointer_binary(expp, oper, expr);
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}
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}
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else {
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arithbalance(expp, oper, &expr);
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non_commutative_binop(expp, oper, expr);
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}
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break;
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case LEFT:
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case RIGHT:
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case LEFTAB:
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case RIGHTAB:
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opnd2integral(expp, oper);
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opnd2integral(&expr, oper);
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arithbalance(expp, oper, &expr); /* ch. 3.3.7 */
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ch3cast(&expr, oper, int_type); /* cvt. rightop to int */
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non_commutative_binop(expp, oper, expr);
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break;
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case '<':
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case '>':
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case LESSEQ:
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case GREATEREQ:
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case EQUAL:
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case NOTEQUAL:
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relbalance(expp, oper, &expr);
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non_commutative_binop(expp, oper, expr);
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(*expp)->ex_type = int_type;
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break;
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case AND:
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case OR:
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opnd2test(expp, oper);
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opnd2test(&expr, oper);
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if (is_cp_cst(*expp)) {
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register struct expr *ex = *expp;
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/* the following condition is a short-hand for
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((oper == AND) && o1) || ((oper == OR) && !o1)
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where o1 == (*expp)->VL_VALUE;
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and ((oper == AND) || (oper == OR))
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*/
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if ((oper == AND) == (ex->VL_VALUE != (arith)0))
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*expp = expr;
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else {
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ex->ex_flags |= expr->ex_flags;
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free_expression(expr);
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*expp = intexpr((arith)((oper == AND) ? 0 : 1),
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INT);
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}
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(*expp)->ex_flags |= ex->ex_flags;
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free_expression(ex);
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}
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else
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if (is_cp_cst(expr)) {
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/* Note!!!: the following condition is a short-hand for
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((oper == AND) && o2) || ((oper == OR) && !o2)
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where o2 == expr->VL_VALUE
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and ((oper == AND) || (oper == OR))
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*/
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if ((oper == AND) == (expr->VL_VALUE != (arith)0)) {
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(*expp)->ex_flags |= expr->ex_flags;
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free_expression(expr);
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}
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else {
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if (oper == OR)
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expr->VL_VALUE = (arith)1;
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ch3bin(expp, ',', expr);
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}
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}
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else {
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*expp = new_oper(int_type, *expp, oper, expr);
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}
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(*expp)->ex_flags |= EX_LOGICAL;
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break;
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case ':':
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if ( is_struct_or_union((*expp)->ex_type->tp_fund)
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|| is_struct_or_union(expr->ex_type->tp_fund)
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) {
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if (!equal_type((*expp)->ex_type, expr->ex_type, 0))
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expr_error(*expp, "illegal balance");
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}
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else
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relbalance(expp, oper, &expr);
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#ifdef LINT
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if ( (is_cp_cst(*expp) && is_cp_cst(expr))
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&& (*expp)->VL_VALUE == expr->VL_VALUE
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) {
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hwarning("operands of : are constant and equal");
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}
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#endif LINT
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*expp = new_oper((*expp)->ex_type, *expp, oper, expr);
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break;
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case '?':
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opnd2logical(expp, oper);
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if (is_cp_cst(*expp)) {
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#ifdef LINT
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hwarning("condition in ?: expression is constant");
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#endif LINT
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*expp = (*expp)->VL_VALUE ?
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expr->OP_LEFT : expr->OP_RIGHT;
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(*expp)->ex_flags |= EX_ILVALUE;
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}
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else {
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*expp = new_oper(expr->ex_type, *expp, oper, expr);
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}
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break;
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case ',':
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if (is_cp_cst(*expp))
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*expp = expr;
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else
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*expp = new_oper(expr->ex_type, *expp, oper, expr);
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(*expp)->ex_flags |= EX_COMMA;
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break;
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}
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}
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pntminuspnt(expp, oper, expr)
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register struct expr **expp, *expr;
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{
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/* Subtracting two pointers is so complicated it merits a
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routine of its own.
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*/
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struct type *up_type = (*expp)->ex_type->tp_up;
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if (!equal_type(up_type, expr->ex_type->tp_up, 0)) {
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expr_error(*expp, "subtracting incompatible pointers");
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free_expression(expr);
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erroneous2int(expp);
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return;
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}
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/* we hope the optimizer will eliminate the load-time
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pointer subtraction
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*/
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*expp = new_oper((*expp)->ex_type, *expp, oper, expr);
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ch3cast(expp, CAST, pa_type); /* ptr-ptr: result has pa_type */
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ch3bin(expp, '/',
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intexpr(size_of_type(up_type, "object"), pa_type->tp_fund));
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ch3cast(expp, CAST, int_type); /* result will be an integer expr */
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}
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mk_binop(expp, oper, expr, commutative)
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struct expr **expp;
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register struct expr *expr;
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{
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/* Constructs in *expp the operation indicated by the operands.
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"commutative" indicates whether "oper" is a commutative
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operator.
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*/
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register struct expr *ex = *expp;
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if (is_cp_cst(expr) && is_cp_cst(ex))
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cstbin(expp, oper, expr);
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else if (is_fp_cst(expr) && is_fp_cst(ex))
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fltcstbin(expp, oper, expr);
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else {
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*expp = (commutative && expr->ex_depth >= ex->ex_depth) ?
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new_oper(ex->ex_type, expr, oper, ex) :
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new_oper(ex->ex_type, ex, oper, expr);
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}
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}
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pointer_arithmetic(expp1, oper, expp2)
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register struct expr **expp1, **expp2;
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{
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int typ;
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/* prepares the integral expression expp2 in order to
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apply it to the pointer expression expp1
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*/
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if ((typ = any2arith(expp2, oper)) == FLOAT
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|| typ == DOUBLE
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|| typ == LNGDBL) {
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expr_error(*expp2,
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"illegal combination of %s and pointer",
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symbol2str(typ));
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erroneous2int(expp2);
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}
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ch3bin( expp2, '*',
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intexpr(size_of_type((*expp1)->ex_type->tp_up, "object"),
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pa_type->tp_fund)
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);
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}
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pointer_binary(expp, oper, expr)
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register struct expr **expp, *expr;
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{
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/* constructs the pointer arithmetic expression out of
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a pointer expression, a binary operator and an integral
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expression.
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*/
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if (is_ld_cst(expr) && is_ld_cst(*expp))
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cstbin(expp, oper, expr);
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else
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*expp = new_oper((*expp)->ex_type, *expp, oper, expr);
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}
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