/*
* (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands.
* See the copyright notice in the ACK home directory, in the file "Copyright".
*/
/* $Header$ */
/* C O D E - G E N E R A T I N G R O U T I N E S */
#include "lint.h"
#ifndef LINT
#include <em.h>
#else
#include "l_em.h"
#include "l_lint.h"
#endif LINT
#include "botch_free.h"
#include <alloc.h>
#include "dataflow.h"
#include "use_tmp.h"
#include "arith.h"
#include "type.h"
#include "idf.h"
#include "label.h"
#include "code.h"
#include "stmt.h"
#include "def.h"
#include "expr.h"
#include "sizes.h"
#include "stack.h"
#include "level.h"
#include "decspecs.h"
#include "declar.h"
#include "Lpars.h"
#include "specials.h"
#include "atw.h"
#include "assert.h"
#include "noRoption.h"
#include "file_info.h"
label lab_count = 1;
label datlab_count = 1;
#ifndef NOFLOAT
int fp_used;
#endif NOFLOAT
/* global function info */
char *func_name;
struct type *func_type;
int func_notypegiven;
#ifdef USE_TMP
static int tmp_id;
static int pro_id;
#endif USE_TMP
extern char options[];
extern char *symbol2str();
#ifndef LINT
init_code(dst_file)
char *dst_file;
{
/* init_code() initialises the output file on which the
compact EM code is written
*/
C_init(word_size, pointer_size); /* initialise EM module */
if (C_open(dst_file) == 0)
fatal("cannot write to %s\n", dst_file);
C_magic();
C_ms_emx(word_size, pointer_size);
#ifdef USE_TMP
#ifdef PREPEND_SCOPES
C_insertpart(tmp_id = C_getid());
#endif USE_TMP
#endif PREPEND_SCOPES
}
#endif LINT
struct string_cst *str_list = 0;
code_string(val, len, dlb)
char *val;
int len;
label dlb;
{
register struct string_cst *sc = new_string_cst();
C_ina_dlb(dlb);
sc->next = str_list;
str_list = sc;
sc->sc_value = val;
sc->sc_len = len;
sc->sc_dlb = dlb;
}
def_strings(sc)
register struct string_cst *sc;
{
while (sc) {
struct string_cst *sc1 = sc;
C_df_dlb(sc->sc_dlb);
str_cst(sc->sc_value, sc->sc_len);
sc = sc->next;
free_string_cst(sc1);
}
}
#ifndef LINT
end_code()
{
/* end_code() performs the actions to be taken when closing
the output stream.
*/
#ifndef NOFLOAT
if (fp_used) {
/* floating point used */
C_ms_flt();
}
#endif NOFLOAT
def_strings(str_list);
str_list = 0;
C_ms_src((int)(LineNumber - 2), FileName);
C_close();
}
#endif LINT
#ifdef PREPEND_SCOPES
prepend_scopes()
{
/* prepend_scopes() runs down the list of global idf's
and generates those exa's, exp's, ina's and inp's
that superior hindsight has provided.
*/
register struct stack_entry *se = local_level->sl_entry;
#ifdef USE_TMP
C_beginpart(tmp_id);
#endif USE_TMP
while (se != 0) {
register struct idf *id = se->se_idf;
register struct def *df = id->id_def;
if (df && (df->df_initialized || df->df_used || df->df_alloc))
code_scope(id->id_text, df);
se = se->next;
}
#ifdef USE_TMP
C_endpart(tmp_id);
#endif USE_TMP
}
#endif PREPEND_SCOPES
code_scope(text, def)
char *text;
register struct def *def;
{
/* generates code for one name, text, of the storage class
as given by def, if meaningful.
*/
int fund = def->df_type->tp_fund;
switch (def->df_sc) {
case EXTERN:
case GLOBAL:
case IMPLICIT:
if (fund == FUNCTION)
C_exp(text);
else
C_exa_dnam(text);
break;
case STATIC:
if (fund == FUNCTION)
C_inp(text);
else
C_ina_dnam(text);
break;
}
}
static label return_label, return2_label;
static char return_expr_occurred;
static arith func_size;
static label func_res_label;
static char *last_fn_given = "";
static label file_name_label;
begin_proc(ds, idf) /* to be called when entering a procedure */
struct decspecs *ds;
struct idf *idf;
{
/* begin_proc() is called at the entrance of a new function
and performs the necessary code generation:
- a scope indicator (if needed) exp/inp
- the procedure entry pro $name
- reserves some space if the result of the function
does not fit in the return area
- a fil pseudo instruction
*/
register char *name = idf->id_text;
register struct def *def = idf->id_def;
while (def->df_level > L_GLOBAL) def = def->next;
/* idf->id_def does not indicate the right def structure
when the function being defined has a parameter of the
same name.
*/
#ifndef PREPEND_SCOPES
code_scope(name, def);
#endif PREPEND_SCOPES
#ifdef DATAFLOW
if (options['d'])
DfaStartFunction(name);
#endif DATAFLOW
/* set global function info */
func_name = name;
if (def->df_type->tp_fund != FUNCTION) {
error("making function body for non-function");
func_type = error_type;
}
else {
func_type = def->df_type->tp_up;
}
func_notypegiven = ds->ds_notypegiven;
func_size = ATW(func_type->tp_size);
#ifndef USE_TMP
C_pro_narg(name);
#else
C_insertpart(pro_id = C_getid());
#endif
if (is_struct_or_union(func_type->tp_fund)) {
C_df_dlb(func_res_label = data_label());
C_bss_cst(func_size, (arith)0, 1);
}
else
func_res_label = 0;
/* Special arrangements if the function result doesn't fit in
the function return area of the EM machine. The size of
the function return area is implementation dependent.
*/
lab_count = (label) 1;
return_label = text_label();
return2_label = text_label();
return_expr_occurred = 0;
LocalInit();
prc_entry(name);
if (! options['L']) { /* profiling */
if (strcmp(last_fn_given, FileName) != 0) {
/* previous function came from other file */
C_df_dlb(file_name_label = data_label());
C_con_scon(last_fn_given = FileName,
(arith)(strlen(FileName) + 1));
}
/* enable debug trace of EM source */
C_fil_dlb(file_name_label, (arith)0);
C_lin((arith)LineNumber);
}
}
end_proc(fbytes)
arith fbytes;
{
/* end_proc() deals with the code to be generated at the end of
a function, as there is:
- the EM ret instruction: "ret 0"
- loading of the function result in the function
result area if there has been a return <expr>
in the function body (see do_return_expr())
- indication of the use of floating points
- indication of the number of bytes used for
formal parameters
- use of special identifiers such as "setjmp"
- "end" + number of bytes used for local variables
*/
arith nbytes;
char optionsn = options['n'];
#ifdef DATAFLOW
if (options['d'])
DfaEndFunction();
#endif DATAFLOW
C_df_ilb(return2_label);
if (return_expr_occurred) C_asp(-func_size);
C_df_ilb(return_label);
prc_exit();
#ifndef LINT
if (return_expr_occurred) {
if (func_res_label != 0) {
C_lae_dlb(func_res_label, (arith)0);
store_block(func_size, func_type->tp_align);
C_lae_dlb(func_res_label, (arith)0);
C_ret(pointer_size);
}
else
C_ret(func_size);
}
else C_ret((arith) 0);
#endif LINT
/* getting the number of "local" bytes is posponed until here,
because copying the function result in "func_res_label" may
need temporaries! However, local_level is now L_FORMAL2, because
L_LOCAL is already unstacked. Therefore, "unstack_level" must
also pass "sl_max_block" to the level above L_LOCAL.
*/
nbytes = ATW(- local_level->sl_max_block);
#ifdef USE_TMP
C_beginpart(pro_id);
C_pro(func_name, nbytes);
#endif
if (fbytes > max_int) {
error("%s has more than %ld parameter bytes",
func_name, (long) max_int);
}
C_ms_par(fbytes); /* # bytes for formals */
if (sp_occurred[SP_SETJMP]) { /* indicate use of "setjmp" */
options['n'] = 1;
C_ms_gto();
sp_occurred[SP_SETJMP] = 0;
}
#ifdef USE_TMP
C_endpart(pro_id);
#endif
LocalFinish();
C_end(nbytes);
if (nbytes > max_int) {
error("%s has more than %ld bytes of local variables",
func_name, (long) max_int);
}
options['n'] = optionsn;
}
do_return()
{
/* do_return handles the case of a return without expression.
This version branches to the return label, which is
probably smarter than generating a direct return.
Return sequences may be expensive.
*/
C_bra(return2_label);
}
do_return_expr(expr)
struct expr *expr;
{
/* do_return_expr() generates the expression and the jump for
a return statement with an expression.
*/
ch7cast(&expr, RETURN, func_type);
code_expr(expr, RVAL, TRUE, NO_LABEL, NO_LABEL);
C_bra(return_label);
return_expr_occurred = 1;
}
code_declaration(idf, expr, lvl, sc)
register struct idf *idf; /* idf to be declared */
struct expr *expr; /* initialisation; NULL if absent */
int lvl; /* declaration level */
int sc; /* storage class, as in the declaration */
{
/* code_declaration() does the actual declaration of the
variable indicated by "idf" on declaration level "lvl".
If the variable is initialised, the expression is given
in "expr", but for global and static initialisations it
is just non-zero, as the expression is not parsed yet.
There are some cases to be considered:
- filter out typedefs, they don't correspond to code;
- global variables, coded only if initialized;
- local static variables;
- local automatic variables;
Since the expression may be modified in the process,
code_declaration() frees it after use, as the caller can
no longer do so.
If there is a storage class indication (EXTERN/STATIC),
code_declaration() will generate an exa or ina.
The sc is the actual storage class, as given in the
declaration. This is to allow:
extern int a;
int a = 5;
while at the same time forbidding
extern int a = 5;
*/
register struct def *def = idf->id_def;
register arith size = def->df_type->tp_size;
int def_sc = def->df_sc;
if (def_sc == TYPEDEF) /* no code for typedefs */
return;
if (sc == EXTERN && expr && !is_anon_idf(idf))
error("%s is extern; cannot initialize", idf->id_text);
if (lvl == L_GLOBAL) { /* global variable */
/* is this an allocating declaration? */
if ( (sc == 0 || sc == STATIC)
&& def->df_type->tp_fund != FUNCTION
&& size >= 0
)
def->df_alloc = ALLOC_SEEN;
if (expr) { /* code only if initialized */
#ifndef PREPEND_SCOPES
code_scope(idf->id_text, def);
#endif PREPEND_SCOPES
def->df_alloc = ALLOC_DONE;
C_df_dnam(idf->id_text);
}
}
else
if (lvl >= L_LOCAL) { /* local variable */
/* STATIC, EXTERN, GLOBAL, IMPLICIT, AUTO or REGISTER */
switch (def_sc) {
case STATIC:
if (def->df_type->tp_fund == FUNCTION) {
/* should produce "inp $function" ??? */
break;
}
/* they are handled on the spot and get an
integer label in EM.
*/
C_df_dlb((label)def->df_address);
if (expr) { /* there is an initialisation */
}
else { /* produce blank space */
if (size <= 0) {
error("size of %s unknown", idf->id_text);
size = (arith)0;
}
C_bss_cst(ATW(size), (arith)0, 1);
}
break;
case EXTERN:
case GLOBAL:
case IMPLICIT:
/* we are sure there is no expression */
break;
case AUTO:
case REGISTER:
if (expr)
loc_init(expr, idf);
break;
default:
crash("bad local storage class");
/*NOTREACHED*/
}
}
}
loc_init(expr, id)
struct expr *expr;
register struct idf *id;
{
/* loc_init() generates code for the assignment of
expression expr to the local variable described by id.
It frees the expression afterwards.
*/
register struct expr *e = expr;
register struct type *tp = id->id_def->df_type;
ASSERT(id->id_def->df_sc != STATIC);
switch (tp->tp_fund) {
case ARRAY:
case STRUCT:
case UNION:
error("automatic %s cannot be initialized in declaration",
symbol2str(tp->tp_fund));
free_expression(e);
return;
}
if (ISCOMMA(e)) { /* embraced: int i = {12}; */
#ifndef NOROPTION
if (options['R']) {
if (ISCOMMA(e->OP_LEFT)) /* int i = {{1}} */
expr_error(e, "extra braces not allowed");
else
if (e->OP_RIGHT != 0) /* int i = {1 , 2} */
expr_error(e, "too many initializers");
}
#endif NOROPTION
while (e) {
loc_init(e->OP_LEFT, id);
e = e->OP_RIGHT;
}
}
else { /* not embraced */
ch7cast(&expr, '=', tp); /* may modify expr */
#ifndef LINT
{
struct value vl;
EVAL(expr, RVAL, TRUE, NO_LABEL, NO_LABEL);
vl.vl_class = Name;
vl.vl_data.vl_idf = id;
vl.vl_value = (arith)0;
store_val(&vl, tp);
}
#else LINT
id->id_def->df_set = 1;
#endif LINT
free_expression(expr);
}
}
bss(idf)
register struct idf *idf;
{
/* bss() allocates bss space for the global idf.
*/
arith size = idf->id_def->df_type->tp_size;
#ifndef PREPEND_SCOPES
code_scope(idf->id_text, idf->id_def);
#endif PREPEND_SCOPES
/* Since bss() is only called if df_alloc is non-zero, and
since df_alloc is only non-zero if size >= 0, we have:
*/
/* but we already gave a warning at the declaration of the
array. Besides, the message given here does not apply to
voids
if (options['R'] && size == 0)
warning("actual array of size 0");
*/
C_df_dnam(idf->id_text);
C_bss_cst(ATW(size), (arith)0, 1);
}
formal_cvt(df)
register struct def *df;
{
/* formal_cvt() converts a formal parameter of type char or
short from int to that type.
*/
register struct type *tp = df->df_type;
if (tp->tp_size != int_size &&
(tp->tp_fund == CHAR || tp->tp_fund == SHORT)
) {
LoadLocal(df->df_address, int_size);
/* conversion(int_type, df->df_type); ???
No, you can't do this on the stack! (CJ)
*/
StoreLocal(df->df_address, tp->tp_size);
}
}
#ifdef LINT
/*ARGSUSED*/
#endif LINT
code_expr(expr, val, code, tlbl, flbl)
struct expr *expr;
label tlbl, flbl;
{
/* code_expr() is the parser's interface to the expression code
generator. If line number trace is wanted, it generates a
lin instruction. EVAL() is called directly.
*/
#ifndef LINT
if (! options['L']) /* profiling */
C_lin((arith)(expr->ex_line));
EVAL(expr, val, code, tlbl, flbl);
#else LINT
lint_expr(expr, code ? USED : IGNORED);
#endif LINT
}
/* The FOR/WHILE/DO/SWITCH stacking mechanism:
stack_stmt() has to be called at the entrance of a
for, while, do or switch statement to indicate the
EM labels where a subsequent break or continue causes
the program to jump to.
*/
static struct stmt_block *stmt_stack; /* top of statement stack */
/* code_break() generates EM code needed at the occurrence of "break":
it generates a branch instruction to the break label of the
innermost statement in which break has a meaning.
As "break" is legal in any of 'while', 'do', 'for' or 'switch',
which are the only ones that are stacked, only the top of
the stack is interesting.
*/
code_break()
{
register struct stmt_block *stmt_block = stmt_stack;
if (stmt_block)
C_bra(stmt_block->st_break);
else
error("break not inside for, while, do or switch");
}
/* code_continue() generates EM code needed at the occurrence of
"continue":
it generates a branch instruction to the continue label of the
innermost statement in which continue has a meaning.
*/
code_continue()
{
register struct stmt_block *stmt_block = stmt_stack;
while (stmt_block) {
if (stmt_block->st_continue) {
C_bra(stmt_block->st_continue);
return;
}
stmt_block = stmt_block->next;
}
error("continue not inside for, while or do");
}
stack_stmt(break_label, cont_label)
label break_label, cont_label;
{
register struct stmt_block *stmt_block = new_stmt_block();
stmt_block->next = stmt_stack;
stmt_block->st_break = break_label;
stmt_block->st_continue = cont_label;
stmt_stack = stmt_block;
}
unstack_stmt()
{
/* unstack_stmt() unstacks the data of a statement
which may contain break or continue
*/
register struct stmt_block *sbp = stmt_stack;
stmt_stack = sbp->next;
free_stmt_block(sbp);
}
static label prc_name;
prc_entry(name)
char *name;
{
if (options['p']) {
C_df_dlb(prc_name = data_label());
C_rom_scon(name, (arith) (strlen(name) + 1));
C_lae_dlb(prc_name, (arith) 0);
C_cal("procentry");
C_asp(pointer_size);
}
}
prc_exit()
{
if (options['p']) {
C_lae_dlb(prc_name, (arith) 0);
C_cal("procexit");
C_asp(pointer_size);
}
}