623 lines
15 KiB
C
623 lines
15 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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/* CODE FOR THE INITIALISATION OF GLOBAL VARIABLES */
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#include "nofloat.h"
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#include <em.h>
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#include "debug.h"
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#include <alloc.h>
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#include "nobitfield.h"
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#include "arith.h"
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#include "align.h"
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#include "label.h"
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#include "expr.h"
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#include "type.h"
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#include "struct.h"
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#include "field.h"
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#include "assert.h"
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#include "Lpars.h"
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#include "class.h"
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#include "sizes.h"
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#include "idf.h"
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#include "level.h"
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#include "def.h"
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#define con_nullbyte() C_con_ucon("0", (arith)1)
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char *symbol2str();
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char *long2str();
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struct expr *do_array(), *do_struct(), *IVAL();
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extern char options[];
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/* do_ival() performs the initialisation of a global variable
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of type tp with the initialisation expression expr by calling IVAL().
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Guided by type tp, the expression is evaluated.
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*/
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do_ival(tpp, ex)
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struct type **tpp;
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struct expr *ex;
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{
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if (IVAL(tpp, ex) != 0)
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too_many_initialisers(ex);
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}
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/* IVAL() recursively guides the initialisation expression through the
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different routines for the different types of initialisation:
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- array initialisation
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- struct initialisation
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- fundamental type initialisation
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Upto now, the initialisation of a union is not allowed!
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An initialisation expression tree consists of normal expressions
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which can be joined together by ',' nodes, which operator acts
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like the lisp function "cons" to build lists.
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IVAL() returns a pointer to the remaining expression tree.
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*/
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struct expr *
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IVAL(tpp, ex)
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struct type **tpp; /* type of global variable */
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register struct expr *ex; /* initialiser expression */
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{
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register struct type *tp = *tpp;
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switch (tp->tp_fund) {
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case ARRAY: /* array initialisation */
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if (valid_type(tp->tp_up, "array element") == 0)
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return 0;
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if (ISCOMMA(ex)) /* list of initialisation expressions */
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return do_array(ex, tpp);
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if (tp->tp_up->tp_fund == CHAR && ex->ex_class == String)
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/* initialisation like char s[] = "I am a string" */
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ch_array(tpp, ex);
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else /* " int i[24] = 12;" */
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check_and_pad(ex, tpp);
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break;
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case STRUCT: /* struct initialisation */
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if (valid_type(tp, "struct") == 0)
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return 0;
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if (ISCOMMA(ex)) /* list of initialisation expressions */
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return do_struct(ex, tp);
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check_and_pad(ex, tpp); /* "struct foo f = 12;" */
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break;
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case UNION:
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error("union initialisation not allowed");
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break;
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case ERRONEOUS:
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break;
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default: /* fundamental type */
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if (ISCOMMA(ex)) { /* " int i = {12};" */
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if (IVAL(tpp, ex->OP_LEFT) != 0)
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too_many_initialisers(ex);
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/* return remainings of the list for the
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other members of the aggregate, if this
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item belongs to an aggregate.
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*/
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return ex->OP_RIGHT;
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}
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check_ival(ex, tp); /* "int i = 12;" */
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break;
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}
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return 0;
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}
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/* do_array() initialises the members of an array described
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by type tp with the expressions in expr.
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Two important cases:
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- the number of members is known
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- the number of members is not known
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In the latter case, do_array() digests the whole expression
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tree it is given.
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In the former case, do_array() eats as many members from
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the expression tree as are needed for the array.
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If there are not sufficient members for the array, the remaining
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members are padded with zeroes
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*/
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struct expr *
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do_array(ex, tpp)
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register struct expr *ex;
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struct type **tpp;
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{
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register struct type *tp = *tpp;
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register arith elem_count;
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ASSERT(tp->tp_fund == ARRAY && ISCOMMA(ex));
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/* the following test catches initialisations like
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char c[] = {"just a string"};
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or
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char d[] = {{"just another string"}};
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The use of the brackets causes this problem.
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Note: although the implementation of such initialisations
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is completely foolish, we did it!! (no applause, thank you)
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*/
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if (tp->tp_up->tp_fund == CHAR) {
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register struct expr *f = ex->OP_LEFT, *g = NILEXPR;
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while (ISCOMMA(f)) { /* eat the brackets!!! */
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g = f;
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f = f->OP_LEFT;
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}
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if (f->ex_class == String) { /* hallelujah, it's a string! */
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ch_array(tpp, f);
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return g ? g->OP_RIGHT : ex->OP_RIGHT;
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}
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/* else: just go on with the next part of this function */
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if (g != 0)
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ex = g;
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}
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if (tp->tp_size == (arith)-1) {
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/* declared with unknown size: [] */
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for (elem_count = 0; ex; elem_count++) {
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/* eat whole initialisation expression */
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if (ISCOMMA(ex->OP_LEFT)) { /* embraced member */
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if (IVAL(&(tp->tp_up), ex->OP_LEFT) != 0)
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too_many_initialisers(ex);
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ex = ex->OP_RIGHT;
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}
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else {
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if (aggregate_type(tp->tp_up))
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ex = IVAL(&(tp->tp_up), ex);
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else {
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check_ival(ex->OP_LEFT, tp->tp_up);
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ex = ex->OP_RIGHT;
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}
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}
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}
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/* set the proper size */
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*tpp = construct_type(ARRAY, tp->tp_up, elem_count);
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}
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else { /* the number of members is already known */
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arith dim = tp->tp_size / tp->tp_up->tp_size;
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for (elem_count = 0; elem_count < dim && ex; elem_count++) {
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if (ISCOMMA(ex->OP_LEFT)) { /* embraced member */
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if (IVAL(&(tp->tp_up), ex->OP_LEFT) != 0)
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too_many_initialisers(ex);
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ex = ex->OP_RIGHT;
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}
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else {
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if (aggregate_type(tp->tp_up))
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ex = IVAL(&(tp->tp_up), ex);
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else {
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check_ival(ex->OP_LEFT, tp->tp_up);
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ex = ex->OP_RIGHT;
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}
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}
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}
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if (ex && elem_count == dim)
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/* all the members are initialised but there
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remains a part of the expression tree which
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is returned
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*/
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return ex;
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if ((ex == 0) && elem_count < dim)
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/* the expression tree is completely absorbed
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but there are still members which must be
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initialised with zeroes
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*/
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do
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pad(tp->tp_up);
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while (++elem_count < dim);
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}
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return 0;
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}
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/* do_struct() initialises a struct of type tp with the expression expr.
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The main loop is just controlled by the definition of the selectors
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during which alignment is taken care of.
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*/
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struct expr *
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do_struct(ex, tp)
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register struct expr *ex;
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register struct type *tp;
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{
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register struct sdef *sd = tp->tp_sdef;
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arith bytes_upto_here = (arith)0;
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arith last_offset = (arith)-1;
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ASSERT(tp->tp_fund == STRUCT && ISCOMMA(ex));
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/* as long as there are selectors and there is an initialiser.. */
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while (sd && ex) {
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if (ISCOMMA(ex->OP_LEFT)) { /* embraced expression */
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if (IVAL(&(sd->sd_type), ex->OP_LEFT) != 0)
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too_many_initialisers(ex);
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ex = ex->OP_RIGHT;
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}
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else {
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if (aggregate_type(sd->sd_type))
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/* selector is an aggregate itself */
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ex = IVAL(&(sd->sd_type), ex);
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else {
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#ifdef NOBITFIELD
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/* fundamental type, not embraced */
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check_ival(ex->OP_LEFT, sd->sd_type);
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ex = ex->OP_RIGHT;
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#else
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if (is_anon_idf(sd->sd_idf))
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/* a hole in the struct due to
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the use of ";:n;" in a struct
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definition.
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*/
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put_bf(sd->sd_type, (arith)0);
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else { /* fundamental type, not embraced */
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check_ival(ex->OP_LEFT, sd->sd_type);
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ex = ex->OP_RIGHT;
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}
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#endif NOBITFIELD
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}
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}
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if (sd->sd_sdef) /* align upto the next selector boundary */
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bytes_upto_here += zero_bytes(sd);
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if (last_offset != sd->sd_offset) {
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/* don't take the field-width more than once */
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bytes_upto_here +=
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size_of_type(sd->sd_type, "selector");
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last_offset = sd->sd_offset;
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}
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sd = sd->sd_sdef;
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}
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/* perfect fit if (ex && (sd == 0)) holds */
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if ((ex == 0) && (sd != 0)) {
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/* there are selectors left which must be padded with zeroes */
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do {
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pad(sd->sd_type);
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/* take care of the alignment restrictions */
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if (sd->sd_sdef)
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bytes_upto_here += zero_bytes(sd);
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/* no field thrown-outs here */
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bytes_upto_here +=
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size_of_type(sd->sd_type, "selector");
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} while (sd = sd->sd_sdef);
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}
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/* keep on aligning... */
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while (bytes_upto_here++ < tp->tp_size)
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con_nullbyte();
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return ex;
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}
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/* check_and_pad() is given a simple initialisation expression
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where the type can be either a simple or an aggregate type.
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In the latter case, only the first member is initialised and
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the rest is zeroed.
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*/
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check_and_pad(ex, tpp)
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register struct expr *ex;
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struct type **tpp;
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{
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/* ex is of a fundamental type */
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register struct type *tp = *tpp;
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if (tp->tp_fund == ARRAY) {
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if (valid_type(tp->tp_up, "array element") == 0)
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return;
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check_and_pad(ex, &(tp->tp_up)); /* first member */
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if (tp->tp_size == (arith)-1)
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/* no size specified upto here: just
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set it to the size of one member.
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*/
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tp = *tpp = construct_type(ARRAY, tp->tp_up, (arith)1);
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else {
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register int dim = tp->tp_size / tp->tp_up->tp_size;
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/* pad remaining members with zeroes */
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while (--dim > 0)
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pad(tp->tp_up);
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}
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}
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else
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if (tp->tp_fund == STRUCT) {
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register struct sdef *sd = tp->tp_sdef;
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if (valid_type(tp, "struct") == 0)
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return;
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check_and_pad(ex, &(sd->sd_type));
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/* next selector is aligned by adding extra zeroes */
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if (sd->sd_sdef)
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zero_bytes(sd);
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while (sd = sd->sd_sdef) { /* pad remaining selectors */
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pad(sd->sd_type);
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if (sd->sd_sdef)
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zero_bytes(sd);
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}
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}
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else /* simple type */
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check_ival(ex, tp);
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}
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/* pad() fills an element of type tp with zeroes.
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If the element is an aggregate, pad() is called recursively.
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*/
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pad(tp)
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register struct type *tp;
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{
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register arith sz = tp->tp_size;
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switch (tp->tp_fund) {
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case ARRAY:
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if (valid_type(tp->tp_up, "array element") == 0)
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return;
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break;
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case STRUCT:
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if (valid_type(tp, "struct") == 0)
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return;
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break;
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case UNION:
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if (valid_type(tp, "union") == 0)
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return;
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if (options['R']) {
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warning("initialisation of unions not allowed");
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}
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break;
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#ifndef NOBITFIELD
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case FIELD:
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put_bf(tp, (arith)0);
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return;
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#endif NOBITFIELD
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case ERRONEOUS:
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return;
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}
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while (sz >= word_size) {
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C_con_cst((arith) 0);
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sz -= word_size;
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}
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while (sz) {
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C_con_icon("0", (arith) 1);
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sz--;
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}
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}
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/* check_ival() checks whether the initialisation of an element
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of a fundamental type is legal and, if so, performs the initialisation
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by directly generating the necessary code.
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No further comment is needed to explain the internal structure
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of this straightforward function.
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*/
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check_ival(expr, tp)
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register struct expr *expr;
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register struct type *tp;
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{
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/* The philosophy here is that ch7cast puts an explicit
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conversion node in front of the expression if the types
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are not compatible. In this case, the initialisation
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expression is no longer a constant.
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*/
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struct expr *ex = expr;
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switch (tp->tp_fund) {
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case CHAR:
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case SHORT:
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case INT:
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case LONG:
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case ENUM:
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case POINTER:
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ch7cast(&ex, '=', tp);
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expr = ex;
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#ifdef DEBUG
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print_expr("init-expr after cast", expr);
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#endif DEBUG
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if (!is_ld_cst(expr))
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illegal_init_cst(expr);
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else
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if (expr->VL_CLASS == Const)
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con_int(expr);
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else
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if (expr->VL_CLASS == Name) {
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register struct idf *idf = expr->VL_IDF;
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if (idf->id_def->df_level >= L_LOCAL)
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illegal_init_cst(expr);
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else /* e.g., int f(); int p = f; */
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if (idf->id_def->df_type->tp_fund == FUNCTION)
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C_con_pnam(idf->id_text);
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else /* e.g., int a; int *p = &a; */
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C_con_dnam(idf->id_text, expr->VL_VALUE);
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}
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else {
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ASSERT(expr->VL_CLASS == Label);
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C_con_dlb(expr->VL_LBL, expr->VL_VALUE);
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}
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break;
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#ifndef NOFLOAT
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case FLOAT:
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case DOUBLE:
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ch7cast(&ex, '=', tp);
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expr = ex;
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#ifdef DEBUG
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print_expr("init-expr after cast", expr);
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#endif DEBUG
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if (expr->ex_class == Float)
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C_con_fcon(expr->FL_VALUE, expr->ex_type->tp_size);
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else
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if (expr->ex_class == Oper && expr->OP_OPER == INT2FLOAT) {
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/* float f = 1; */
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expr = expr->OP_RIGHT;
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if (is_cp_cst(expr))
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C_con_fcon(long2str((long)expr->VL_VALUE, 10),
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tp->tp_size);
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else
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illegal_init_cst(expr);
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}
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else
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illegal_init_cst(expr);
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break;
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#endif NOFLOAT
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#ifndef NOBITFIELD
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case FIELD:
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ch7cast(&ex, '=', tp->tp_up);
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expr = ex;
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#ifdef DEBUG
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print_expr("init-expr after cast", expr);
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#endif DEBUG
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if (is_cp_cst(expr))
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put_bf(tp, expr->VL_VALUE);
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else
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illegal_init_cst(expr);
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break;
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#endif NOBITFIELD
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|
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case ERRONEOUS:
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break;
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default:
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crash("check_ival");
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}
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}
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|
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/* ch_array() initialises an array of characters when given
|
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a string constant.
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Alignment is taken care of.
|
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*/
|
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ch_array(tpp, ex)
|
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struct type **tpp; /* type tp = array of characters */
|
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struct expr *ex;
|
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{
|
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register struct type *tp = *tpp;
|
|
register arith length = ex->SG_LEN;
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char *s;
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|
arith ntopad;
|
|
|
|
ASSERT(ex->ex_class == String);
|
|
if (tp->tp_size == (arith)-1) {
|
|
/* set the dimension */
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tp = *tpp = construct_type(ARRAY, tp->tp_up, length);
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ntopad = align(tp->tp_size, word_align) - tp->tp_size;
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}
|
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else {
|
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arith dim = tp->tp_size / tp->tp_up->tp_size;
|
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extern char options[];
|
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|
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if (length > dim) {
|
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if (options['R'])
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too_many_initialisers(ex);
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else { /* don't take the null byte into account */
|
|
if (length > dim + 1)
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expr_warning(ex,
|
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"too many initialisers");
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length = dim;
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}
|
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}
|
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ntopad = align(dim, word_align) - length;
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}
|
|
/* throw out the characters of the already prepared string */
|
|
s = Malloc((int) (length + ntopad));
|
|
clear(s, (int) (length + ntopad));
|
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strncpy(s, ex->SG_VALUE, (int) length);
|
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str_cst(s, (int) (length + ntopad));
|
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free(s);
|
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}
|
|
|
|
/* As long as some parts of the pipeline cannot handle very long string
|
|
constants, string constants are written out in chunks
|
|
*/
|
|
str_cst(str, len)
|
|
register char *str;
|
|
register int len;
|
|
{
|
|
arith chunksize = ((127 + word_size) / word_size) * word_size;
|
|
|
|
while (len > chunksize) {
|
|
C_con_scon(str, chunksize);
|
|
len -= chunksize;
|
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str += chunksize;
|
|
}
|
|
C_con_scon(str, (arith) len);
|
|
}
|
|
|
|
#ifndef NOBITFIELD
|
|
/* put_bf() takes care of the initialisation of (bit-)field
|
|
selectors of a struct: each time such an initialisation takes place,
|
|
put_bf() is called instead of the normal code generating routines.
|
|
Put_bf() stores the given integral value into "field" and
|
|
"throws" the result of "field" out if the current selector
|
|
is the last of this number of fields stored at the same address.
|
|
*/
|
|
put_bf(tp, val)
|
|
struct type *tp;
|
|
arith val;
|
|
{
|
|
static long field = (arith)0;
|
|
static arith offset = (arith)-1;
|
|
register struct field *fd = tp->tp_field;
|
|
register struct sdef *sd = fd->fd_sdef;
|
|
static struct expr exp;
|
|
|
|
ASSERT(sd);
|
|
if (offset == (arith)-1) {
|
|
/* first bitfield in this field */
|
|
offset = sd->sd_offset;
|
|
exp.ex_type = tp->tp_up;
|
|
exp.ex_class = Value;
|
|
exp.VL_CLASS = Const;
|
|
}
|
|
if (val != 0) /* insert the value into "field" */
|
|
field |= (val & fd->fd_mask) << fd->fd_shift;
|
|
if (sd->sd_sdef == 0 || sd->sd_sdef->sd_offset != offset) {
|
|
/* the selector was the last stored at this address */
|
|
exp.VL_VALUE = field;
|
|
con_int(&exp);
|
|
field = (arith)0;
|
|
offset = (arith)-1;
|
|
}
|
|
}
|
|
#endif NOBITFIELD
|
|
|
|
int
|
|
zero_bytes(sd)
|
|
register struct sdef *sd;
|
|
{
|
|
/* fills the space between a selector of a struct
|
|
and the next selector of that struct with zero-bytes.
|
|
*/
|
|
register int n = sd->sd_sdef->sd_offset - sd->sd_offset -
|
|
size_of_type(sd->sd_type, "struct member");
|
|
register int count = n;
|
|
|
|
while (n-- > 0)
|
|
con_nullbyte();
|
|
return count;
|
|
}
|
|
|
|
int
|
|
valid_type(tp, str)
|
|
struct type *tp;
|
|
char *str;
|
|
{
|
|
if (tp->tp_size < 0) {
|
|
error("size of %s unknown", str);
|
|
return 0;
|
|
}
|
|
return 1;
|
|
}
|
|
|
|
con_int(ex)
|
|
register struct expr *ex;
|
|
{
|
|
register struct type *tp = ex->ex_type;
|
|
|
|
ASSERT(is_cp_cst(ex));
|
|
if (tp->tp_unsigned)
|
|
C_con_ucon(long2str((long)ex->VL_VALUE, -10), tp->tp_size);
|
|
else
|
|
C_con_icon(long2str((long)ex->VL_VALUE, 10), tp->tp_size);
|
|
}
|
|
|
|
illegal_init_cst(ex)
|
|
struct expr *ex;
|
|
{
|
|
expr_error(ex, "illegal initialisation constant");
|
|
}
|
|
|
|
too_many_initialisers(ex)
|
|
struct expr *ex;
|
|
{
|
|
expr_error(ex, "too many initialisers");
|
|
}
|
|
|
|
aggregate_type(tp)
|
|
register struct type *tp;
|
|
{
|
|
return tp->tp_fund == ARRAY || tp->tp_fund == STRUCT;
|
|
}
|