ack/lang/cem/cemcom/stack.c

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/* $Header$ */
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/* S T A C K / U N S T A C K R O U T I N E S */
#include <system.h>
#include <em.h>
#include <em_reg.h>
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#include "debug.h"
#include "use_tmp.h"
#include "botch_free.h"
#include "alloc.h"
#include "Lpars.h"
#include "arith.h"
#include "stack.h"
#include "type.h"
#include "idf.h"
#include "def.h"
#include "struct.h"
#include "storage.h"
#include "level.h"
#include "mes.h"
/* #include <em_reg.h> */
extern char options[];
static struct stack_level UniversalLevel;
struct stack_level *local_level = &UniversalLevel;
/* The main reason for having this secondary stacking
mechanism besides the linked lists pointed to by the idf's
is efficiency.
To remove the idf's of a given level, one could scan the
hash table and chase down the idf chains; with a hash
table size of 100 this is feasible, but with a size of say
100000 this becomes painful. Therefore all idf's are also
kept in a stack of sets, one set for each level.
*/
int level; /* Always equal to local_level->sl_level. */
stack_level() {
/* A new level is added on top of the identifier stack.
*/
struct stack_level *stl = new_stack_level();
clear((char *)stl, sizeof(struct stack_level));
local_level->sl_next = stl;
stl->sl_previous = local_level;
stl->sl_level = ++level;
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stl->sl_local_offset =
stl->sl_max_block = local_level->sl_local_offset;
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local_level = stl;
}
stack_idf(idf, stl)
struct idf *idf;
struct stack_level *stl;
{
/* The identifier idf is inserted in the stack on level stl.
*/
register struct stack_entry *se = new_stack_entry();
clear((char *)se, sizeof(struct stack_entry));
/* link it into the stack level */
se->next = stl->sl_entry;
se->se_idf = idf;
stl->sl_entry = se;
}
struct stack_level *
stack_level_of(lvl)
{
/* The stack_level corresponding to level lvl is returned.
The stack should probably be an array, to be extended with
realloc where needed.
*/
if (lvl == level)
return local_level;
else {
register struct stack_level *stl = &UniversalLevel;
while (stl->sl_level != lvl)
stl = stl->sl_next;
return stl;
}
/*NOTREACHED*/
}
unstack_level()
{
/* The top level of the identifier stack is removed.
*/
struct stack_level *lastlvl;
#ifdef DEBUG
if (options['t'])
dumpidftab("before unstackidfs", 0);
#endif DEBUG
/* The implementation below is more careful than strictly
necessary. Optimists may optimize it afterwards.
*/
while (local_level->sl_entry) {
register struct stack_entry *se = local_level->sl_entry;
register struct idf *idf = se->se_idf;
register struct def *def;
register struct sdef *sdef;
register struct tag *tag;
/* unlink it from the local stack level */
local_level->sl_entry = se->next;
free_stack_entry(se);
while ((def = idf->id_def) && def->df_level >= level) {
/* unlink it from the def list under the idf block */
if (def->df_sc == LABEL)
unstack_label(idf);
else
if (level == L_LOCAL || level == L_FORMAL1) {
if ( def->df_register != REG_NONE &&
def->df_sc != STATIC &&
options['n'] == 0
) {
int reg;
switch (def->df_type->tp_fund) {
case POINTER:
reg = reg_pointer;
break;
case FLOAT:
case DOUBLE:
reg = reg_float;
break;
default:
reg = reg_any;
break;
}
C_ms_reg(def->df_address,
def->df_type->tp_size,
reg, def->df_register
);
}
}
idf->id_def = def->next;
free_def(def);
update_ahead(idf);
}
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while ( (sdef = idf->id_sdef)
&& sdef->sd_level >= level
) {
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/* unlink it from the sdef list under the idf block */
idf->id_sdef = sdef->next;
free_sdef(sdef);
}
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while ( (tag = idf->id_struct)
&& tag->tg_level >= level
) {
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/* unlink it from the struct list under the idf block */
idf->id_struct = tag->next;
free_tag(tag);
}
while ((tag = idf->id_enum) && tag->tg_level >= level) {
/* unlink it from the enum list under the idf block */
idf->id_enum = tag->next;
free_tag(tag);
}
}
/* Unlink the local stack level from the stack.
*/
lastlvl = local_level;
local_level = local_level->sl_previous;
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if ( level > L_LOCAL
&& lastlvl->sl_max_block < local_level->sl_max_block
) {
local_level->sl_max_block = lastlvl->sl_max_block;
}
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free_stack_level(lastlvl);
local_level->sl_next = (struct stack_level *) 0;
level = local_level->sl_level;
#ifdef DEBUG
if (options['t'])
dumpidftab("after unstackidfs", 0);
#endif DEBUG
}
unstack_world()
{
/* The global level of identifiers is scanned, and final
decisions are taken about such issues as
extern/static/global and un/initialized.
Effects on the code generator: initialised variables
have already been encoded while the uninitialised ones
are not and have to be encoded at this moment.
*/
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register struct stack_entry *se = local_level->sl_entry;
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open_name_list();
while (se) {
register struct idf *idf = se->se_idf;
register struct def *def = idf->id_def;
if (!def) {
/* global selectors, etc. */
se = se->next;
continue;
}
#ifdef DEBUG
if (options['a']) {
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char *symbol2str();
print("\"%s\", %s, %s, %s, %s\n",
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idf->id_text,
(def->df_alloc == 0) ? "no alloc" :
(def->df_alloc == ALLOC_SEEN) ? "alloc seen" :
(def->df_alloc == ALLOC_DONE) ? "alloc done" :
"illegal alloc info",
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symbol2str(def->df_sc),
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def->df_initialized ? "init" : "no init",
def->df_used ? "used" : "not used");
}
#endif DEBUG
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/*
/_* find final storage class *_/
if (def->df_sc == GLOBAL || def->df_sc == IMPLICIT)
/_* even now we still don't know *_/
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def->df_sc = EXTERN;
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*/
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if ( def->df_sc == STATIC
&& def->df_type->tp_fund == FUNCTION
&& !def->df_initialized
) {
/* orphaned static function */
if (options['R'])
warning("static function %s never defined, %s",
idf->id_text,
"changed to extern"
);
def->df_sc = EXTERN;
}
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if (
def->df_alloc == ALLOC_SEEN &&
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!def->df_initialized
) {
/* space must be allocated */
bss(idf);
namelist(idf->id_text); /* may be common */
def->df_alloc = ALLOC_DONE; /* see Note below */
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}
se = se->next;
}
/* Note:
df_alloc must be set to ALLOC_DONE because the idf entry
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may occur several times in the list.
The reason for this is that the same name may be used
for different purposes on the same level, e.g.
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struct s {int s;} s;
is a legal definition and contains 3 defining occurrences
of s.
Each definition has been entered into the identifier stack.
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Although only one of them concerns a variable, we meet the
s 3 times when scanning the identifier stack.
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*/
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}
/* A list of potential common names is kept, to be fed to
an understanding loader. The list is written to a file
the name of which is nmlist. If nmlist == NULL, no name
list is generated.
*/
extern char *nmlist; /* BAH! -- main.c */
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static File *nfp = 0;
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open_name_list()
{
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if (nmlist && sys_open(nmlist, OP_WRITE, &nfp) == 0)
fatal("cannot create namelist %s", nmlist);
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}
namelist(nm)
char *nm;
{
if (nmlist) {
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sys_write(nfp, nm, strlen(nm));
sys_write(nfp, "\n", 1);
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}
}