ack/lang/pc/comp/declar.g
1993-11-16 11:54:00 +00:00

1012 lines
22 KiB
Plaintext

/* D E C L A R A T I O N S */
{
/* next line DEBUG */
#include "debug.h"
#include <alloc.h>
#include <assert.h>
#include <em_arith.h>
#include <em_label.h>
#include <pc_file.h>
#include "LLlex.h"
#include "chk_expr.h"
#include "def.h"
#include "idf.h"
#include "main.h"
#include "misc.h"
#include "node.h"
#include "scope.h"
#include "type.h"
#include "dbsymtab.h"
#define PC_BUFSIZ (sizeof(struct file) - (int)((struct file *)0)->bufadr)
int proclevel = 0; /* nesting level of procedures */
int parlevel = 0; /* nesting level of parametersections */
int expect_label = 0; /* so the parser knows that we expect a label */
static int in_type_defs; /* in type definition part or not */
}
/* ISO section 6.2.1, p. 93 */
Block(struct def *df;)
{
arith i;
} :
{ text_label = (label) 0; }
LabelDeclarationPart
Module(df, &i)
CompoundStatement
{ if( !err_occurred )
CodeEndBlock(df, i);
if( df ) EndBlock(df);
FreeNode(BlockScope->sc_lablist);
}
;
LabelDeclarationPart
{
struct node *nd;
} :
[
LABEL Label(&nd)
{ if( nd ) {
DeclLabel(nd);
nd->nd_next = CurrentScope->sc_lablist;
CurrentScope->sc_lablist = nd;
}
}
[ %persistent
',' Label(&nd)
{ if( nd ) {
DeclLabel(nd);
nd->nd_next = CurrentScope->sc_lablist;
CurrentScope->sc_lablist = nd;
}
}
]*
';'
]?
;
Module(struct def *df; arith *i;)
{
label save_label;
} :
ConstantDefinitionPart
{ in_type_defs = 1; }
TypeDefinitionPart
{ in_type_defs = 0;
/* resolve forward references */
chk_forw_types();
}
VariableDeclarationPart
{ if( !proclevel ) {
chk_prog_params();
BssVar();
}
proclevel++;
save_label = text_label;
}
ProcedureAndFunctionDeclarationPart
{ text_label = save_label;
proclevel--;
chk_directives();
/* needed with labeldefinitions
and for-statement
*/
BlockScope = CurrentScope;
if( !err_occurred )
*i = CodeBeginBlock( df );
}
;
ConstantDefinitionPart:
[
CONST
[ %persistent
ConstantDefinition ';'
]+
]?
;
TypeDefinitionPart:
[
TYPE
[ %persistent
TypeDefinition ';'
]+
]?
;
VariableDeclarationPart:
[
VAR
[ %persistent
VariableDeclaration ';'
]+
]?
;
ProcedureAndFunctionDeclarationPart:
[
[
ProcedureDeclaration
|
FunctionDeclaration
] ';'
]*
;
/* ISO section 6.1.6, p. 92 */
Label(struct node **pnd;)
{
char lab[5];
extern char *sprint();
} : { expect_label = 1; }
INTEGER /* not really an integer, in [0..9999] */
{ if( dot.TOK_INT < 0 || dot.TOK_INT > 9999 ) {
if( dot.TOK_INT != -1 ) /* This means insertion */
error("label must lie in closed interval [0..9999]");
*pnd = NULLNODE;
}
else {
sprint(lab, "%d", (int) dot.TOK_INT);
*pnd = MkLeaf(Name, &dot);
(*pnd)->nd_IDF = str2idf(lab, 1);
}
expect_label = 0;
}
;
/* ISO section 6.3, p. 95 */
ConstantDefinition
{
register struct idf *id;
register struct def *df;
struct node *nd;
} :
IDENT { id = dot.TOK_IDF; }
'=' Constant(&nd)
{ if( df = define(id,CurrentScope,D_CONST) ) {
df->con_const = nd;
df->df_type = nd->nd_type;
df->df_flags |= D_SET;
#ifdef DBSYMTAB
if (options['g']) stb_string(df, D_CONST);
#endif /* DBSYMTAB */
}
}
;
/* ISO section 6.4.1, p. 96 */
TypeDefinition
{
register struct idf *id;
register struct def *df;
struct type *tp;
} :
IDENT { id = dot.TOK_IDF; }
'=' TypeDenoter(&tp)
{ if( df = define(id, CurrentScope, D_TYPE) ) {
df->df_type = tp;
df->df_flags |= D_SET;
#ifdef DBSYMTAB
if (options['g']) stb_string(df, D_TYPE);
#endif /* DBSYMTAB */
}
}
;
TypeDenoter(register struct type **ptp;):
/* This is a changed rule, because the grammar as specified in the
* reference is not LL(1), and this gives conflicts.
*/
TypeIdentifierOrSubrangeType(ptp)
|
PointerType(ptp)
|
StructuredType(ptp)
|
EnumeratedType(ptp)
;
TypeIdentifierOrSubrangeType(register struct type **ptp;)
{
struct node *nd1, *nd2;
} :
/* This is a new rule because the grammar specified by the standard
* is not exactly LL(1) (see TypeDenoter).
*/
[
%prefer
IDENT { nd1 = MkLeaf(Name, &dot); }
[
/* empty */
/* at this point IDENT must be a TypeIdentifier !! */
{ chk_type_id(ptp, nd1);
FreeNode(nd1);
}
|
/* at this point IDENT must be a Constant !! */
{ (void) ChkConstant(nd1); }
UPTO Constant(&nd2)
{ *ptp = subr_type(nd1, nd2);
FreeNode(nd1);
FreeNode(nd2);
}
]
|
Constant(&nd1) UPTO Constant(&nd2)
{ *ptp = subr_type(nd1, nd2);
FreeNode(nd1);
FreeNode(nd2);
}
]
;
TypeIdentifier(register struct type **ptp;):
IDENT { register struct node *nd = MkLeaf(Name, &dot);
chk_type_id(ptp, nd);
FreeNode(nd);
}
;
/* ISO section 6.5.1, p. 105 */
VariableDeclaration
{
struct node *VarList;
struct type *tp;
} :
IdentifierList(&VarList) ':' TypeDenoter(&tp)
{ EnterVarList(VarList, tp, proclevel > 0); }
;
/* ISO section 6.6.1, p. 108 */
ProcedureDeclaration
{
struct node *nd;
struct type *tp;
register struct scopelist *scl;
register struct def *df;
} :
/* This is a changed rule, because the grammar as specified in the
* reference is not LL(1), and this gives conflicts.
*
* ProcedureHeading without a FormalParameterList can be a
* ProcedureIdentification, i.e. the IDENT used in the Heading is
* also used in a "forward" declaration.
*/
{ open_scope(); }
ProcedureHeading(&nd, &tp) ';'
{ scl = CurrVis; close_scope(0); }
[
Directive
{ DoDirective(dot.TOK_IDF, nd, tp, scl, 0); }
|
{ df = DeclProc(nd, tp, scl);
#ifdef DBSYMTAB
if (options['g']) stb_string(df, D_PROCEDURE);
#endif /* DBSYMTAB */
}
Block(df)
{ /* open_scope() is simulated in DeclProc() */
#ifdef DBSYMTAB
if (options['g']) stb_string(df, D_PEND);
#endif /* DBSYMTAB */
close_scope(1);
}
]
;
ProcedureHeading(register struct node **pnd; register struct type **ptp;)
{
struct node *fpl;
} :
PROCEDURE
IDENT {
*pnd = MkLeaf(Name, &dot);
}
[
FormalParameterList(&fpl)
{ arith nb_pars = 0;
struct paramlist *pr = 0;
if( !parlevel )
/* procedure declaration */
nb_pars = EnterParamList(fpl, &pr);
else
/* procedure parameter */
nb_pars = EnterParTypes(fpl, &pr);
*ptp = proc_type(pr, nb_pars);
FreeNode(fpl);
}
|
/* empty */
{ *ptp =
proc_type((struct paramlist *)0,
(proclevel > 1) ? pointer_size : (arith) 0);
}
]
;
Directive:
/* see also Functiondeclaration (6.6.2, p. 110)
* Not actually an identifier but 'letter {letter | digit}'
*/
IDENT
;
/* ISO section 6.6.1, p. 108 */
FunctionDeclaration
{
struct node *nd;
struct type *tp;
register struct scopelist *scl;
register struct def *df;
} :
/* This is a changed rule, because the grammar as specified in the
* reference is not LL(1), and this gives conflicts.
*/
{ open_scope(); }
FunctionHeading(&nd, &tp) ';'
{ scl = CurrVis; close_scope(0); }
[
Directive
{ if( !tp ) {
node_error(nd,
"function \"%s\": illegal declaration",
nd->nd_IDF->id_text);
}
else DoDirective(dot.TOK_IDF, nd, tp, scl, 1);
}
|
{ if( df = DeclFunc(nd, tp, scl) ) {
df->prc_res =
- ResultType(df->df_type)->tp_size;
df->prc_bool =
CurrentScope->sc_off =
df->prc_res - int_size;
#ifdef DBSYMTAB
if (options['g']) stb_string(df, D_FUNCTION);
#endif /* DBSYMTAB */
}
}
Block(df)
{ if( df ) {
#ifdef DBSYMTAB
if (options['g']) stb_string(df, D_PEND);
#endif /* DBSYMTAB */
EndFunc(df);
}
/* open_scope() is simulated in DeclFunc() */
close_scope(1);
}
]
;
FunctionHeading(register struct node **pnd; register struct type **ptp;)
{
/* This is the Function AND FunctionIdentification part.
If it is a identification, *ptp is set to NULLTYPE.
*/
struct node *fpl = NULLNODE;
struct type *tp;
struct paramlist *pr = 0;
arith nb_pars = (proclevel > 1) ? pointer_size : 0;
} :
FUNCTION
IDENT { *pnd = MkLeaf(Name, &dot);
*ptp = NULLTYPE;
}
[
[
FormalParameterList(&fpl)
{ if( !parlevel )
/* function declaration */
nb_pars = EnterParamList(fpl, &pr);
else
/* function parameter */
nb_pars = EnterParTypes(fpl, &pr);
}
|
/* empty */
]
':' TypeIdentifier(&tp)
{ if( IsConstructed(tp) ) {
node_error(*pnd,
"function has an illegal result type");
tp = error_type;
}
*ptp = func_type(pr, nb_pars, tp);
FreeNode(fpl);
}
]?
;
/* ISO section 6.4.2.1, p. 96 */
OrdinalType(register struct type **ptp;):
/* This is a changed rule, because the grammar as specified in the
* reference states that a SubrangeType can start with an IDENT and
* so can an OrdinalTypeIdentifier, and this is not LL(1).
*/
TypeIdentifierOrSubrangeType(ptp)
|
EnumeratedType(ptp)
;
/* ISO section 6.4.2.3, p. 97 */
EnumeratedType(register struct type **ptp;)
{
struct node *EnumList;
arith i = (arith) 1;
} :
'(' IdentifierList(&EnumList) ')'
{ register struct type *tp =
standard_type(T_ENUMERATION, word_align, word_size);
*ptp = tp;
EnterEnumList(EnumList, tp);
if( tp->enm_ncst == 0 )
*ptp = error_type;
else do {
if( ufit(tp->enm_ncst-1, i) ) {
tp->tp_psize = i;
tp->tp_palign = i;
break;
}
i <<= 1;
} while( i < word_size );
}
;
IdentifierList(register struct node **nd;)
{
register struct node *tnd;
} :
IDENT { *nd = tnd = MkLeaf(Name, &dot); }
[ %persistent
',' IDENT
{ tnd->nd_next = MkLeaf(Name, &dot);
tnd = tnd->nd_next;
}
]*
;
/* ISO section 6.4.3.2, p. 98 */
StructuredType(register struct type **ptp;)
{
unsigned short packed = 0;
} :
[
PACKED { packed = T_PACKED; }
]?
UnpackedStructuredType(ptp, packed)
;
UnpackedStructuredType(register struct type **ptp; unsigned short packed;):
ArrayType(ptp, packed)
|
RecordType(ptp, packed)
|
SetType(ptp, packed)
|
FileType(ptp)
;
/* ISO section 6.4.3.2, p. 98 */
ArrayType(register struct type **ptp; unsigned short packed;)
{
struct type *tp;
register struct type *tp2;
} :
ARRAY
'['
Indextype(&tp)
{ *ptp = tp2 = construct_type(T_ARRAY, tp);
tp2->tp_flags |= packed;
}
[ %persistent
',' Indextype(&tp)
{ tp2->arr_elem = construct_type(T_ARRAY, tp);
tp2 = tp2->arr_elem;
tp2->tp_flags |= packed;
}
]*
']'
OF ComponentType(&tp)
{ tp2->arr_elem = tp;
ArraySizes(*ptp);
if( tp->tp_flags & T_HASFILE )
(*ptp)->tp_flags |= T_HASFILE;
}
;
Indextype(register struct type **ptp;):
OrdinalType(ptp)
;
ComponentType(register struct type **ptp;):
TypeDenoter(ptp)
;
/* ISO section 6.4.3.3, p. 99 */
RecordType(register struct type **ptp; unsigned short packed;)
{
register struct scope *scope;
register struct def *df;
struct selector *sel = 0;
arith size = 0;
int xalign = struct_align;
} :
RECORD
{ open_scope(); /* scope for fields of record */
scope = CurrentScope;
close_scope(0);
}
FieldList(scope, &size, &xalign, packed, &sel)
{ if( size == 0 ) {
warning("empty record declaration");
size = 1;
}
*ptp = standard_type(T_RECORD, xalign, size);
(*ptp)->rec_scope = scope;
(*ptp)->rec_sel = sel;
(*ptp)->tp_flags |= packed;
/* copy the file component flag */
df = scope->sc_def;
while( df && !(df->df_type->tp_flags & T_HASFILE) )
df = df->df_nextinscope;
if( df )
(*ptp)->tp_flags |= T_HASFILE;
}
END
;
FieldList(struct scope *scope; arith *cnt; int *palign; unsigned short packed;
struct selector **sel;):
/* This is a changed rule, because the grammar as specified in the
* reference is not LL(1), and this gives conflicts.
* Those irritating, annoying (Siklossy !!) semicolons.
*/
/* empty */
|
FixedPart(scope, cnt, palign, packed, sel)
|
VariantPart(scope, cnt, palign, packed, sel)
;
FixedPart(struct scope *scope; arith *cnt; int *palign; unsigned short packed;
struct selector **sel;):
/* This is a changed rule, because the grammar as specified in the
* reference is not LL(1), and this gives conflicts.
* Again those frustrating semicolons !!
*/
RecordSection(scope, cnt, palign, packed)
FixedPartTail(scope, cnt, palign, packed, sel)
;
FixedPartTail(struct scope *scope; arith *cnt; int *palign;
unsigned short packed; struct selector **sel;):
/* This is a new rule because the grammar specified by the standard
* is not exactly LL(1).
* We see the light at the end of the tunnel !
*/
/* empty */
|
%default
';'
[
/* empty */
|
VariantPart(scope, cnt, palign, packed, sel)
|
RecordSection(scope, cnt, palign, packed)
FixedPartTail(scope, cnt, palign, packed, sel)
]
;
RecordSection(struct scope *scope; arith *cnt; int *palign;
unsigned short packed;)
{
struct node *FldList;
struct type *tp;
} :
IdentifierList(&FldList) ':' TypeDenoter(&tp)
{ *palign =
lcm(*palign, packed ? tp->tp_palign : word_align);
EnterFieldList(FldList, tp, scope, cnt, packed);
}
;
VariantPart(struct scope *scope; arith *cnt; int *palign;
unsigned short packed; struct selector **sel;)
{
struct type *tp;
struct def *df = 0;
struct idf *id = 0;
arith tcnt, max;
register arith ncst = 0;/* the number of values of the tagtype */
register struct selector **sp;
extern char *Malloc();
} :
/* This is a changed rule, because the grammar as specified in the
* reference is not LL(1), and this gives conflicts.
* We're almost there !!
*/
{ *sel = (struct selector *) Malloc(sizeof(struct selector));
(*sel)->sel_ptrs = 0;
}
CASE
VariantSelector(&tp, &id)
{ if (id)
df = define(id, scope, D_FIELD);
/* ISO 6.4.3.3 (p. 100)
* The standard permits the integertype as tagtype, but demands that the set
* of values denoted by the case-constants is equal to the set of values
* specified by the tagtype.
*/
if( !(tp->tp_fund & T_INDEX)) {
error("illegal type in variant");
tp = error_type;
}
else {
arith lb, ub;
getbounds(tp, &lb, &ub);
ncst = ub - lb + 1;
if (ncst < 0 || ncst > (~(1L<<(8*sizeof(arith)-1)))/sizeof(struct selector *)) {
error("range of variant tag too wide");
tp = error_type;
}
else {
/* initialize selector */
(*sel)->sel_ptrs = (struct selector **)
Malloc((unsigned)ncst * sizeof(struct selector *));
(*sel)->sel_ncst = ncst;
(*sel)->sel_lb = lb;
/* initialize tagvalue-table */
sp = (*sel)->sel_ptrs;
while( ncst-- ) *sp++ = *sel;
}
}
(*sel)->sel_type = tp;
if( df ) {
df->df_type = tp;
df->fld_flags |=
packed ? (F_PACKED | F_SELECTOR) : F_SELECTOR;
df->fld_off = align(*cnt,
packed ? tp->tp_palign : tp->tp_align);
*cnt = df->fld_off +
(packed ? tp->tp_psize : tp->tp_size);
}
tcnt = *cnt;
}
OF
Variant(scope, &tcnt, palign, packed, *sel)
{ max = tcnt; }
VariantTail(scope, &tcnt, &max, cnt, palign, packed, *sel)
{ *cnt = max;
if( sp = (*sel)->sel_ptrs ) {
int errflag = 0;
ncst = (*sel)->sel_ncst;
while( ncst-- )
if( *sp == *sel ) {
*sp++ = 0;
errflag = 1;
}
else *sp++;
if( errflag )
error("record variant part: each tagvalue must have a variant");
}
}
;
VariantTail(register struct scope *scope; arith *tcnt; arith *max; arith *cnt;
int *palign; unsigned short packed; struct selector *sel;):
/* This is a new rule because the grammar specified by the standard
* is not exactly LL(1).
* At last, the garden of Eden !!
*/
/* empty */
|
%default
';'
[
/* empty */
|
{ *tcnt = *cnt; }
Variant(scope, tcnt, palign, packed, sel)
{ if( *tcnt > *max ) *max = *tcnt; }
VariantTail(scope, tcnt, max, cnt, palign, packed, sel)
]
;
VariantSelector(register struct type **ptp; register struct idf **pid;)
{
register struct node *nd;
} :
/* This is a changed rule, because the grammar as specified in the
* reference is not LL(1), and this gives conflicts.
*/
IDENT { nd = MkLeaf(Name, &dot); }
[
/* Old fashioned ! at this point the IDENT represents
* the TagType
*/
{ warning("old-fashioned syntax ':' missing");
chk_type_id(ptp, nd);
FreeNode(nd);
}
|
/* IDENT is now the TagField */
':'
TypeIdentifier(ptp)
{ *pid = nd->nd_IDF;
FreeNode(nd);
}
]
;
Variant(struct scope *scope; arith *cnt; int *palign; unsigned short packed;
struct selector *sel;)
{
struct node *nd;
struct selector *sel1 = 0;
} :
CaseConstantList(&nd)
':'
'(' FieldList(scope, cnt, palign, packed, &sel1) ')'
{ TstCaseConstants(nd, sel, sel1);
FreeNode(nd);
}
;
CaseConstantList(struct node **nd;)
{
struct node *nd1;
} :
Constant(&nd1) { *nd = nd1; }
[ %persistent
',' Constant(&(nd1->nd_next))
{ nd1 = nd1->nd_next; }
]*
;
/* ISO section 6.4.3.4, p. 101 */
SetType(register struct type **ptp; unsigned short packed;):
SET OF OrdinalType(ptp)
{ *ptp = set_type(*ptp, packed); }
;
/* ISO section 6.4.3.5, p. 101 */
FileType(register struct type **ptp;):
FILE OF
{ *ptp = construct_type(T_FILE, NULLTYPE);
(*ptp)->tp_flags |= T_HASFILE;
}
ComponentType(&(*ptp)->next)
{ if( (*ptp)->next->tp_flags & T_HASFILE ) {
error("file type has an illegal component type");
(*ptp)->next = error_type;
}
else {
if( (*ptp)->next->tp_size > PC_BUFSIZ )
(*ptp)->tp_size = (*ptp)->tp_psize =
(*ptp)->next->tp_size +
sizeof(struct file) - PC_BUFSIZ;
}
}
;
/* ISO section 6.4.4, p. 103 */
PointerType(register struct type **ptp;)
{
register struct node *nd;
register struct def *df;
} :
'^'
{ *ptp = construct_type(T_POINTER, NULLTYPE); }
IDENT
{ nd = MkLeaf(Name, &dot);
df = lookup(nd->nd_IDF, CurrentScope, D_INUSE);
/* if( !df && CurrentScope == GlobalScope)
df = lookup(nd->nd_IDF, PervasiveScope, D_INUSE);
*/
if( in_type_defs &&
(!df || (df->df_kind & (D_ERROR | D_FORWTYPE)))
)
/* forward declarations only in typedefintion
part
*/
Forward(nd, *ptp);
else {
chk_type_id(&(*ptp)->next, nd);
FreeNode(nd);
}
}
;
/* ISO section 6.6.3.1, p. 112 */
FormalParameterList(struct node **pnd;)
{
struct node *nd;
} :
'('
{ *pnd = nd = MkLeaf(Link, &dot); }
FormalParameterSection(nd)
[ %persistent
{ nd->nd_right = MkLeaf(Link, &dot);
nd = nd->nd_right;
}
';' FormalParameterSection(nd)
]*
')'
;
FormalParameterSection(struct node *nd;):
/* This is a changed rule, because the grammar as specified
* in the reference is not LL(1), and this gives conflicts.
*/
{ /* kind of parameter */
nd->nd_INT = 0;
}
[
[
/* ValueParameterSpecification */
/* empty */
{ nd->nd_INT = (D_VALPAR | D_SET); }
|
/* VariableParameterSpecification */
VAR
{ nd->nd_INT = (D_VARPAR | D_USED); }
]
IdentifierList(&(nd->nd_left)) ':'
[
/* ISO section 6.6.3.7.1, p. 115 */
/* ConformantArrayParameterSpecification */
ConformantArraySchema(&(nd->nd_type))
|
TypeIdentifier(&(nd->nd_type))
]
{ if( nd->nd_type->tp_flags & T_HASFILE &&
(nd->nd_INT & D_VALPAR) ) {
error("value parameter can't have a filecomponent");
nd->nd_type = error_type;
}
}
|
ProceduralParameterSpecification(&(nd->nd_left), &(nd->nd_type))
{ nd->nd_INT = (D_VALPAR | D_SET); }
|
FunctionalParameterSpecification(&(nd->nd_left), &(nd->nd_type))
{ nd->nd_INT = (D_VALPAR | D_SET); }
]
;
ProceduralParameterSpecification(register struct node **pnd;
register struct type **ptp;):
{ parlevel++; }
ProcedureHeading(pnd, ptp)
{ parlevel--; }
;
FunctionalParameterSpecification(register struct node **pnd;
register struct type **ptp;):
{ parlevel++; }
FunctionHeading(pnd, ptp)
{ parlevel--;
if( !*ptp ) {
node_error(*pnd,
"illegal function parameter declaration");
*ptp = error_type;
}
}
;
ConformantArraySchema(register struct type **ptp;):
PackedConformantArraySchema(ptp)
|
%default
UnpackedConformantArraySchema(ptp)
;
PackedConformantArraySchema(register struct type **ptp;)
{
struct type *tp;
} :
PACKED ARRAY
{ tp = construct_type(T_ARRAY, NULLTYPE);
tp->tp_flags |= T_PACKED;
}
'['
Index_TypeSpecification(ptp, tp)
{ tp->next = *ptp; }
']'
OF TypeIdentifier(ptp)
{ if( (*ptp)->tp_flags & T_HASFILE )
tp->tp_flags |= T_HASFILE;
tp->arr_elem = *ptp;
*ptp = tp;
}
;
UnpackedConformantArraySchema(register struct type **ptp;)
{
struct type *tp, *tp2;
} :
ARRAY
{ *ptp = tp = construct_type(T_ARRAY,NULLTYPE);}
'['
Index_TypeSpecification(&tp2, tp)
{ tp->next = tp2; }
[
{ tp->arr_elem =
construct_type(T_ARRAY, NULLTYPE);
tp = tp->arr_elem;
}
';' Index_TypeSpecification(&tp2, tp)
{ tp->next = tp2; }
]*
']'
OF
[
TypeIdentifier(&tp2)
|
ConformantArraySchema(&tp2)
]
{ if( tp2->tp_flags & T_HASFILE )
(*ptp)->tp_flags |= T_HASFILE;
tp->arr_elem = tp2;
}
;
Index_TypeSpecification(register struct type **ptp; register struct type *tp;)
{
register struct def *df1, *df2;
} :
IDENT
{ if( df1 =
define(dot.TOK_IDF, CurrentScope, D_LBOUND)) {
df1->bnd_type = tp; /* type conf. array */
df1->df_flags |= D_SET;
}
}
UPTO
IDENT
{ if( df2 =
define(dot.TOK_IDF, CurrentScope, D_UBOUND)) {
df2->bnd_type = tp; /* type conf. array */
df2->df_flags |= D_SET;
}
}
':' TypeIdentifier(ptp)
{ if( !bounded(*ptp) &&
(*ptp)->tp_fund != T_INTEGER ) {
error("Indextypespecification: illegal type");
*ptp = error_type;
}
df1->df_type = df2->df_type = *ptp;
}
;