print_type_qualifiers(type->type.qualifiers);
const char *s;
- switch(type->atype) {
+ switch(type->akind) {
case ATOMIC_TYPE_INVALID: s = "INVALIDATOMIC"; break;
case ATOMIC_TYPE_VOID: s = "void"; break;
case ATOMIC_TYPE_BOOL: s = "_Bool"; break;
intern_print_type_post(type->element_type, false);
}
+static void print_bitfield_type_post(const bitfield_type_t *type)
+{
+ fputs(" : ", out);
+ print_expression(type->size);
+ intern_print_type_post(type->base, false);
+}
+
void print_enum_definition(const declaration_t *declaration)
{
fputs("{\n", out);
static void print_typedef_type_pre(const typedef_type_t *const type)
{
+ print_type_qualifiers(type->type.qualifiers);
fputs(type->declaration->symbol->string, out);
}
case TYPE_POINTER:
print_pointer_type_pre(&type->pointer);
return;
+ case TYPE_BITFIELD:
+ intern_print_type_pre(type->bitfield.base, top);
+ return;
case TYPE_ARRAY:
print_array_type_pre(&type->array);
return;
case TYPE_ARRAY:
print_array_type_post(&type->array);
return;
+ case TYPE_BITFIELD:
+ print_bitfield_type_post(&type->bitfield);
+ return;
case TYPE_INVALID:
case TYPE_ATOMIC:
case TYPE_ENUM:
case TYPE_BUILTIN: return sizeof(builtin_type_t);
case TYPE_TYPEDEF: return sizeof(typedef_type_t);
case TYPE_TYPEOF: return sizeof(typeof_type_t);
+ case TYPE_BITFIELD: return sizeof(bitfield_type_t);
case TYPE_INVALID: panic("invalid type found");
}
panic("unknown type found");
if(type->kind != TYPE_ATOMIC)
return false;
- switch(type->atomic.atype) {
+ switch(type->atomic.akind) {
case ATOMIC_TYPE_BOOL:
case ATOMIC_TYPE_CHAR:
case ATOMIC_TYPE_SCHAR:
if(type->kind != TYPE_ATOMIC)
return false;
- switch(type->atomic.atype) {
+ switch(type->atomic.akind) {
case ATOMIC_TYPE_FLOAT:
case ATOMIC_TYPE_DOUBLE:
case ATOMIC_TYPE_LONG_DOUBLE:
if(type->kind != TYPE_ATOMIC)
return false;
- switch(type->atomic.atype) {
+ switch(type->atomic.akind) {
case ATOMIC_TYPE_CHAR:
case ATOMIC_TYPE_SCHAR:
case ATOMIC_TYPE_SHORT:
{
assert(!is_typeref(type));
+ if(type->kind == TYPE_BITFIELD)
+ return true;
+
if(is_type_integer(type) || is_type_floating(type))
return true;
switch (type->kind) {
case TYPE_POINTER: return true;
case TYPE_BUILTIN: return is_type_scalar(type->builtin.real_type);
- default: break;
+ default: break;
}
return is_type_arithmetic(type);
declaration_t *declaration = compound_type->declaration;
return !declaration->init.is_defined;
}
+ case TYPE_BITFIELD:
case TYPE_FUNCTION:
return true;
return type->array.size == NULL;
case TYPE_ATOMIC:
+ return type->atomic.akind == ATOMIC_TYPE_VOID;
+
case TYPE_POINTER:
case TYPE_ENUM:
case TYPE_BUILTIN:
static bool function_types_compatible(const function_type_t *func1,
const function_type_t *func2)
{
- if(!types_compatible(func1->return_type, func2->return_type))
+ const type_t* const ret1 = skip_typeref(func1->return_type);
+ const type_t* const ret2 = skip_typeref(func2->return_type);
+ if (!types_compatible(ret1, ret2))
return false;
/* can parameters be compared? */
return false;
if(array1->size != NULL && array2->size != NULL) {
- /* TODO: check if size expression evaulate to the same value
+ /* TODO: check if size expression evaluate to the same value
* if they are constant */
}
case TYPE_FUNCTION:
return function_types_compatible(&type1->function, &type2->function);
case TYPE_ATOMIC:
- return type1->atomic.atype == type2->atomic.atype;
+ return type1->atomic.akind == type2->atomic.akind;
case TYPE_ARRAY:
return array_types_compatible(&type1->array, &type2->array);
- case TYPE_POINTER:
- return types_compatible(type1->pointer.points_to,
- type2->pointer.points_to);
+
+ case TYPE_POINTER: {
+ const type_t *const to1 = skip_typeref(type1->pointer.points_to);
+ const type_t *const to2 = skip_typeref(type2->pointer.points_to);
+ return types_compatible(to1, to2);
+ }
+
case TYPE_COMPOUND_STRUCT:
case TYPE_COMPOUND_UNION:
case TYPE_ENUM:
/* TODO: not implemented */
break;
+ case TYPE_BITFIELD:
+ /* not sure if this makes sense or is even needed, implement it if you
+ * really need it! */
+ panic("type compatibility check for bitfield type");
+
case TYPE_INVALID:
panic("invalid type found in compatible types");
case TYPE_TYPEDEF:
type_t *skip_typeref(type_t *type)
{
- unsigned qualifiers = type->base.qualifiers;
+ unsigned qualifiers = TYPE_QUALIFIER_NONE;
- while(1) {
+ while(true) {
switch(type->kind) {
case TYPE_TYPEDEF: {
qualifiers |= type->base.qualifiers;
break;
}
+ if (qualifiers != TYPE_QUALIFIER_NONE) {
+ type_t *const copy = duplicate_type(type);
+ copy->base.qualifiers |= qualifiers;
+
+ type = typehash_insert(copy);
+ if (type != copy) {
+ obstack_free(type_obst, copy);
+ }
+ }
+
return type;
}
return result;
}
-type_t *make_atomic_type(atomic_type_type_t atype, type_qualifiers_t qualifiers)
+type_t *make_atomic_type(atomic_type_kind_t atype, type_qualifiers_t qualifiers)
{
type_t *type = obstack_alloc(type_obst, sizeof(atomic_type_t));
memset(type, 0, sizeof(atomic_type_t));
type->kind = TYPE_ATOMIC;
type->base.qualifiers = qualifiers;
- type->atomic.atype = atype;
+ type->atomic.akind = atype;
return identify_new_type(type);
}