ack/lang/cem/cemcom/statement.g

399 lines
5.2 KiB
Plaintext

/* $Header$ */
/* STATEMENT SYNTAX PARSER */
{
#include <em.h>
#include "debug.h"
#include "botch_free.h"
#include "arith.h"
#include "LLlex.h"
#include "type.h"
#include "idf.h"
#include "label.h"
#include "expr.h"
#include "code.h"
#include "storage.h"
#include "stack.h"
#include "def.h"
extern int level;
}
/* Each statement construction is stacked in order to trace a
statement to such a construction. Example: a case statement should
be recognized as a piece of the most enclosing switch statement.
*/
/* 9 */
statement
:
[%if (AHEAD != ':')
expression_statement
|
label ':' statement
|
compound_statement((arith *)0)
|
if_statement
|
while_statement
|
do_statement
|
for_statement
|
switch_statement
|
case_statement
|
default_statement
|
break_statement
|
continue_statement
|
return_statement
|
jump
|
';'
|
asm_statement
]
;
expression_statement
{ struct expr *expr;
}
:
expression(&expr)
';'
{
#ifdef DEBUG
print_expr("Full expression", expr);
#endif DEBUG
code_expr(expr, RVAL, FALSE, NO_LABEL, NO_LABEL);
free_expression(expr);
}
;
label
{ struct idf *idf;
}
:
identifier(&idf)
{
/* This allows the following absurd case:
typedef int grz;
main() {
grz: printf("A labelled statement\n");
}
*/
define_label(idf);
C_df_ilb((label)idf->id_def->df_address);
}
;
if_statement
{
struct expr *expr;
label l_true = text_label();
label l_false = text_label();
label l_end = text_label();
}
:
IF
'('
expression(&expr)
{
opnd2test(&expr, IF);
if (is_cp_cst(expr)) {
/* The comparison has been optimized
to a 0 or 1.
*/
if (expr->VL_VALUE == (arith)0) {
C_bra(l_false);
}
/* else fall through */
}
else {
code_expr(expr, RVAL, TRUE, l_true, l_false);
C_df_ilb(l_true);
}
free_expression(expr);
}
')'
statement
[%prefer
ELSE
{
C_bra(l_end);
C_df_ilb(l_false);
}
statement
{ C_df_ilb(l_end);
}
|
empty
{ C_df_ilb(l_false);
}
]
;
while_statement
{
struct expr *expr;
label l_break = text_label();
label l_continue = text_label();
label l_body = text_label();
}
:
WHILE
{
stack_stmt(l_break, l_continue);
C_df_ilb(l_continue);
}
'('
expression(&expr)
{
opnd2test(&expr, WHILE);
if (is_cp_cst(expr)) {
if (expr->VL_VALUE == (arith)0) {
C_bra(l_break);
}
}
else {
code_expr(expr, RVAL, TRUE, l_body, l_break);
C_df_ilb(l_body);
}
}
')'
statement
{
C_bra(l_continue);
C_df_ilb(l_break);
unstack_stmt();
free_expression(expr);
}
;
do_statement
{ struct expr *expr;
label l_break = text_label();
label l_continue = text_label();
label l_body = text_label();
}
:
DO
{ C_df_ilb(l_body);
stack_stmt(l_break, l_continue);
}
statement
WHILE
'('
{ C_df_ilb(l_continue);
}
expression(&expr)
{
opnd2test(&expr, WHILE);
if (is_cp_cst(expr)) {
if (expr->VL_VALUE == (arith)1) {
C_bra(l_body);
}
}
else {
code_expr(expr, RVAL, TRUE, l_body, l_break);
}
C_df_ilb(l_break);
}
')'
';'
{
unstack_stmt();
free_expression(expr);
}
;
for_statement
{ struct expr *e_init = 0, *e_test = 0, *e_incr = 0;
label l_break = text_label();
label l_continue = text_label();
label l_body = text_label();
label l_test = text_label();
}
:
FOR
{ stack_stmt(l_break, l_continue);
}
'('
[
expression(&e_init)
{ code_expr(e_init, RVAL, FALSE, NO_LABEL, NO_LABEL);
}
]?
';'
{ C_df_ilb(l_test);
}
[
expression(&e_test)
{
opnd2test(&e_test, FOR);
if (is_cp_cst(e_test)) {
if (e_test->VL_VALUE == (arith)0) {
C_bra(l_break);
}
}
else {
code_expr(e_test, RVAL, TRUE, l_body, l_break);
C_df_ilb(l_body);
}
}
]?
';'
expression(&e_incr)?
')'
statement
{
C_df_ilb(l_continue);
if (e_incr)
code_expr(e_incr, RVAL, FALSE,
NO_LABEL, NO_LABEL);
C_bra(l_test);
C_df_ilb(l_break);
unstack_stmt();
free_expression(e_init);
free_expression(e_test);
free_expression(e_incr);
}
;
switch_statement
{
struct expr *expr;
}
:
SWITCH
'('
expression(&expr)
{
code_startswitch(&expr);
}
')'
statement
{
code_endswitch();
free_expression(expr);
}
;
case_statement
{
struct expr *expr;
}
:
CASE
constant_expression(&expr)
{
code_case(expr);
free_expression(expr);
}
':'
statement
;
default_statement
:
DEFAULT
{
code_default();
}
':'
statement
;
break_statement
:
BREAK
{code_break();}
';'
;
continue_statement
:
CONTINUE
{code_continue();}
';'
;
return_statement
{ struct expr *expr = 0;
}
:
RETURN
[
expression(&expr)
{
do_return_expr(expr);
free_expression(expr);
}
|
empty
{
do_return();
}
]
';'
;
jump
{ struct idf *idf;
}
:
GOTO
identifier(&idf)
';'
{
apply_label(idf);
C_bra((label)idf->id_def->df_address);
}
;
compound_statement(arith *nbytes;):
'{'
{
stack_level();
}
[%while (AHEAD != ':') /* >>> conflict on TYPE_IDENTIFIER */
declaration
]*
[%persistent
statement
]*
'}'
{
if (nbytes)
*nbytes = (- local_level->sl_max_block);
unstack_level();
}
;
asm_statement
{ char *asm_bts;
int asm_len;
}
:
ASM
'('
STRING
{ asm_bts = dot.tk_bts;
asm_len = dot.tk_len;
}
')'
';'
{ code_asm(asm_bts, asm_len);
}
;