/** TYPE **/
/*-----------------------------------------------------------------*/
-type *firm_none_type; type *get_none_type(void) { return firm_none_type; }
-type *firm_unknown_type; type *get_unknown_type(void) { return firm_unknown_type; }
+ir_type *firm_none_type; ir_type *get_none_type(void) { return firm_none_type; }
+ir_type *firm_unknown_type; ir_type *get_unknown_type(void) { return firm_unknown_type; }
#ifdef DEBUG_libfirm
/*
* Creates a new type representation.
*/
-type *
+ir_type *
new_type(tp_op *type_op, ir_mode *mode, ident *name, dbg_info *db) {
- type *res;
+ ir_type *res;
int node_size;
assert(type_op != type_id);
assert(!id_contains_char(name, ' ') && "type name should not contain spaces");
- node_size = offsetof(type, attr) + type_op->attr_size;
+ node_size = offsetof(ir_type, attr) + type_op->attr_size;
res = xmalloc(node_size);
memset(res, 0, node_size);
return res;
}
-void free_type(type *tp) {
+void free_type(ir_type *tp) {
const tp_op *op = get_type_tpop(tp);
if ((get_type_tpop(tp) == tpop_none) || (get_type_tpop(tp) == tpop_unknown))
remove_irp_type(tp);
/* Free the attributes of the type. */
free_type_attrs(tp);
- /* Free entities automatically allocated with the type */
+ /* Free entities automatically allocated with the ir_type */
if (op->ops.free_auto_entities)
op->ops.free_auto_entities(tp);
/* And now the type itself... */
free(tp);
}
-void free_type_entities(type *tp) {
+void free_type_entities(ir_type *tp) {
const tp_op *tpop = get_type_tpop(tp);
if (tpop->ops.free_entities)
tpop->ops.free_entities(tp);
}
-void free_type_attrs(type *tp) {
+void free_type_attrs(ir_type *tp) {
const tp_op *tpop = get_type_tpop(tp);
if (tpop->ops.free_attrs)
}
/* set/get the link field */
-void *(get_type_link)(const type *tp) {
+void *(get_type_link)(const ir_type *tp) {
return _get_type_link(tp);
}
-void (set_type_link)(type *tp, void *l) {
+void (set_type_link)(ir_type *tp, void *l) {
_set_type_link(tp, l);
}
-const tp_op *(get_type_tpop)(const type *tp) {
+const tp_op *(get_type_tpop)(const ir_type *tp) {
return _get_type_tpop(tp);
}
-ident *(get_type_tpop_nameid)(const type *tp) {
+ident *(get_type_tpop_nameid)(const ir_type *tp) {
return _get_type_tpop_nameid(tp);
}
-const char* get_type_tpop_name(const type *tp) {
+const char* get_type_tpop_name(const ir_type *tp) {
assert(tp && tp->kind == k_type);
return get_id_str(tp->type_op->name);
}
-tp_opcode (get_type_tpop_code)(const type *tp) {
+tp_opcode (get_type_tpop_code)(const ir_type *tp) {
return _get_type_tpop_code(tp);
}
-ir_mode *(get_type_mode)(const type *tp) {
+ir_mode *(get_type_mode)(const ir_type *tp) {
return _get_type_mode(tp);
}
-void set_type_mode(type *tp, ir_mode *mode) {
+void set_type_mode(ir_type *tp, ir_mode *mode) {
const tp_op *tpop = get_type_tpop(tp);
if (tpop->ops.set_type_mode)
assert(0 && "setting a mode is NOT allowed for this type");
}
-ident *(get_type_ident)(const type *tp) {
+ident *(get_type_ident)(const ir_type *tp) {
return _get_type_ident(tp);
}
-void (set_type_ident)(type *tp, ident* id) {
+void (set_type_ident)(ir_type *tp, ident* id) {
_set_type_ident(tp, id);
}
/* Outputs a unique number for this node */
-long get_type_nr(const type *tp) {
+long get_type_nr(const ir_type *tp) {
assert(tp);
#ifdef DEBUG_libfirm
return tp->nr;
#endif
}
-const char* get_type_name(const type *tp) {
+const char* get_type_name(const ir_type *tp) {
assert(tp && tp->kind == k_type);
return (get_id_str(tp->name));
}
-int (get_type_size_bytes)(const type *tp) {
+int (get_type_size_bytes)(const ir_type *tp) {
return _get_type_size_bytes(tp);
}
-int (get_type_size_bits)(const type *tp) {
+int (get_type_size_bits)(const ir_type *tp) {
return _get_type_size_bits(tp);
}
-visibility get_type_visibility (const type *tp) {
+visibility get_type_visibility (const ir_type *tp) {
#if 0
visibility res = visibility_local;
if (is_compound_type(tp)) {
return tp->visibility;
}
-void set_type_visibility (type *tp, visibility v) {
+void set_type_visibility (ir_type *tp, visibility v) {
assert(is_type(tp));
#if 0
/* check for correctness */
}
void
-set_type_size_bits(type *tp, int size) {
+set_type_size_bits(ir_type *tp, int size) {
const tp_op *tpop = get_type_tpop(tp);
if (tpop->ops.set_type_size)
}
void
-set_type_size_bytes(type *tp, int size) {
+set_type_size_bytes(ir_type *tp, int size) {
set_type_size_bits(tp, 8*size);
}
-int get_type_alignment_bytes(type *tp) {
+int get_type_alignment_bytes(ir_type *tp) {
int align = get_type_alignment_bits(tp);
return align < 0 ? align : (align + 7) >> 3;
}
-int get_type_alignment_bits(type *tp) {
+int get_type_alignment_bits(ir_type *tp) {
int align = 8;
if (tp->align > 0)
align = 0;
for (i = 0; i < n; ++i) {
- type *t = get_entity_type(get_compound_member(tp, i));
+ ir_type *t = get_entity_type(get_compound_member(tp, i));
int a = get_type_alignment_bits(t);
if (a > align)
}
void
-set_type_alignment_bits(type *tp, int align) {
+set_type_alignment_bits(ir_type *tp, int align) {
assert(tp && tp->kind == k_type);
/* Methods don't have an alignment. */
if (tp->type_op != type_method) {
}
void
-set_type_alignment_bytes(type *tp, int align) {
+set_type_alignment_bytes(ir_type *tp, int align) {
set_type_alignment_bits(tp, 8*align);
}
}
-type_state (get_type_state)(const type *tp) {
+type_state (get_type_state)(const ir_type *tp) {
return _get_type_state(tp);
}
void
-set_type_state(type *tp, type_state state) {
+set_type_state(ir_type *tp, type_state state) {
assert(tp && tp->kind == k_type);
if ((tp->type_op == type_pointer) || (tp->type_op == type_primitive) ||
tp->state = state;
}
-unsigned long (get_type_visited)(const type *tp) {
+unsigned long (get_type_visited)(const ir_type *tp) {
return _get_type_visited(tp);
}
-void (set_type_visited)(type *tp, unsigned long num) {
+void (set_type_visited)(ir_type *tp, unsigned long num) {
_set_type_visited(tp, num);
}
/* Sets visited field in type to type_visited. */
-void (mark_type_visited)(type *tp) {
+void (mark_type_visited)(ir_type *tp) {
_mark_type_visited(tp);
}
-int (type_visited)(const type *tp) {
+int (type_visited)(const ir_type *tp) {
return _type_visited(tp);
}
-int (type_not_visited)(const type *tp) {
+int (type_not_visited)(const ir_type *tp) {
return _type_not_visited(tp);
}
}
/* Checks whether two types are structural equal.*/
-int equal_type(type *typ1, type *typ2) {
+int equal_type(ir_type *typ1, ir_type *typ2) {
entity **m;
- type **t;
+ ir_type **t;
int i, j;
if (typ1 == typ2) return 1;
memset(t, 0, sizeof(entity *) * get_class_n_supertypes(typ1));
/* First sort the supertypes of typ2 */
for (i = 0; i < get_class_n_supertypes(typ1); i++) {
- type *t1 = get_class_supertype(typ1, i);
+ ir_type *t1 = get_class_supertype(typ1, i);
for (j = 0; j < get_class_n_supertypes(typ2); j++) {
- type *t2 = get_class_supertype(typ2, j);
+ ir_type *t2 = get_class_supertype(typ2, j);
if (get_type_ident(t2) == get_type_ident(t1))
t[i] = t2;
}
}
/* Checks whether two types are structural comparable. */
-int smaller_type (type *st, type *lt) {
+int smaller_type (ir_type *st, ir_type *lt) {
entity **m;
int i, j;
}
} break;
case tpo_array: {
- type *set, *let; /* small/large elt. type */
+ ir_type *set, *let; /* small/large elt. ir_type */
if (get_array_n_dimensions(st) != get_array_n_dimensions(lt))
return 0;
set = get_array_element_type(st);
/* TYPE_CLASS */
/*-----------------------------------------------------------------*/
-/* create a new class type */
-type *new_d_type_class (ident *name, dbg_info *db) {
- type *res;
+/* create a new class ir_type */
+ir_type *new_d_type_class (ident *name, dbg_info *db) {
+ ir_type *res;
res = new_type(type_class, NULL, name, db);
res->attr.ca.members = NEW_ARR_F (entity *, 0);
- res->attr.ca.subtypes = NEW_ARR_F (type *, 0);
- res->attr.ca.supertypes = NEW_ARR_F (type *, 0);
+ res->attr.ca.subtypes = NEW_ARR_F (ir_type *, 0);
+ res->attr.ca.supertypes = NEW_ARR_F (ir_type *, 0);
res->attr.ca.peculiarity = peculiarity_existent;
res->attr.ca.dfn = 0;
hook_new_type(res);
return res;
}
-type *new_type_class (ident *name) {
+ir_type *new_type_class (ident *name) {
return new_d_type_class (name, NULL);
}
-void free_class_entities(type *clss) {
+void free_class_entities(ir_type *clss) {
int i;
assert(clss && (clss->type_op == type_class));
for (i = get_class_n_members(clss) - 1; i >= 0; --i)
free_entity(get_class_member(clss, i));
}
-void free_class_attrs(type *clss) {
+void free_class_attrs(ir_type *clss) {
assert(clss && (clss->type_op == type_class));
DEL_ARR_F(clss->attr.ca.members);
DEL_ARR_F(clss->attr.ca.subtypes);
}
/* manipulate private fields of class type */
-void add_class_member (type *clss, entity *member) {
+void add_class_member (ir_type *clss, entity *member) {
assert(clss && (clss->type_op == type_class));
assert(clss != get_entity_type(member) && "recursive type");
ARR_APP1 (entity *, clss->attr.ca.members, member);
}
-int (get_class_n_members) (const type *clss) {
+int (get_class_n_members) (const ir_type *clss) {
return _get_class_n_members(clss);
}
-int get_class_member_index(type *clss, entity *mem) {
+int get_class_member_index(ir_type *clss, entity *mem) {
int i;
assert(clss && (clss->type_op == type_class));
for (i = 0; i < get_class_n_members(clss); i++)
return -1;
}
-entity *(get_class_member) (const type *clss, int pos) {
+entity *(get_class_member) (const ir_type *clss, int pos) {
return _get_class_member(clss, pos);
}
-entity *get_class_member_by_name(type *clss, ident *name) {
+entity *get_class_member_by_name(ir_type *clss, ident *name) {
int i, n_mem;
assert(clss && (clss->type_op == type_class));
n_mem = get_class_n_members(clss);
return NULL;
}
-void set_class_member (type *clss, entity *member, int pos) {
+void set_class_member (ir_type *clss, entity *member, int pos) {
assert(clss && (clss->type_op == type_class));
assert(pos >= 0 && pos < get_class_n_members(clss));
clss->attr.ca.members[pos] = member;
}
-void set_class_members (type *clss, entity **members, int arity) {
+void set_class_members (ir_type *clss, entity **members, int arity) {
int i;
assert(clss && (clss->type_op == type_class));
DEL_ARR_F(clss->attr.ca.members);
ARR_APP1 (entity *, clss->attr.ca.members, members[i]);
}
}
-void remove_class_member(type *clss, entity *member) {
+void remove_class_member(ir_type *clss, entity *member) {
int i;
assert(clss && (clss->type_op == type_class));
for (i = 0; i < (ARR_LEN (clss->attr.ca.members)); i++) {
}
}
-void add_class_subtype (type *clss, type *subtype) {
+void add_class_subtype (ir_type *clss, ir_type *subtype) {
int i;
assert(clss && (clss->type_op == type_class));
- ARR_APP1 (type *, clss->attr.ca.subtypes, subtype);
+ ARR_APP1 (ir_type *, clss->attr.ca.subtypes, subtype);
for (i = 0; i < get_class_n_supertypes(subtype); i++)
if (get_class_supertype(subtype, i) == clss)
/* Class already registered */
return;
- ARR_APP1 (type *, subtype->attr.ca.supertypes, clss);
+ ARR_APP1 (ir_type *, subtype->attr.ca.supertypes, clss);
}
-int get_class_n_subtypes (const type *clss) {
+int get_class_n_subtypes (const ir_type *clss) {
assert(clss && (clss->type_op == type_class));
return (ARR_LEN (clss->attr.ca.subtypes));
}
-type *get_class_subtype (type *clss, int pos) {
+ir_type *get_class_subtype (ir_type *clss, int pos) {
assert(clss && (clss->type_op == type_class));
assert(pos >= 0 && pos < get_class_n_subtypes(clss));
return clss->attr.ca.subtypes[pos] = skip_tid(clss->attr.ca.subtypes[pos]);
}
-int get_class_subtype_index(type *clss, const type *subclass) {
+int get_class_subtype_index(ir_type *clss, const ir_type *subclass) {
int i, n_subtypes = get_class_n_subtypes(clss);
assert(is_Class_type(subclass));
for (i = 0; i < n_subtypes; ++i) {
}
return -1;
}
-void set_class_subtype (type *clss, type *subtype, int pos) {
+void set_class_subtype (ir_type *clss, ir_type *subtype, int pos) {
assert(clss && (clss->type_op == type_class));
assert(pos >= 0 && pos < get_class_n_subtypes(clss));
clss->attr.ca.subtypes[pos] = subtype;
}
-void remove_class_subtype(type *clss, type *subtype) {
+void remove_class_subtype(ir_type *clss, ir_type *subtype) {
int i;
assert(clss && (clss->type_op == type_class));
for (i = 0; i < (ARR_LEN (clss->attr.ca.subtypes)); i++)
}
}
-void add_class_supertype (type *clss, type *supertype) {
+void add_class_supertype (ir_type *clss, ir_type *supertype) {
int i;
assert(clss && (clss->type_op == type_class));
assert(supertype && (supertype -> type_op == type_class));
- ARR_APP1 (type *, clss->attr.ca.supertypes, supertype);
+ ARR_APP1 (ir_type *, clss->attr.ca.supertypes, supertype);
for (i = get_class_n_subtypes(supertype) - 1; i >= 0; --i)
if (get_class_subtype(supertype, i) == clss)
/* Class already registered */
return;
- ARR_APP1 (type *, supertype->attr.ca.subtypes, clss);
+ ARR_APP1 (ir_type *, supertype->attr.ca.subtypes, clss);
}
-int get_class_n_supertypes (const type *clss) {
+int get_class_n_supertypes (const ir_type *clss) {
assert(clss && (clss->type_op == type_class));
return (ARR_LEN (clss->attr.ca.supertypes));
}
-int get_class_supertype_index(type *clss, type *super_clss) {
+int get_class_supertype_index(ir_type *clss, ir_type *super_clss) {
int i, n_supertypes = get_class_n_supertypes(clss);
assert(super_clss && (super_clss->type_op == type_class));
for (i = 0; i < n_supertypes; i++)
return i;
return -1;
}
-type *get_class_supertype (type *clss, int pos) {
+ir_type *get_class_supertype (ir_type *clss, int pos) {
assert(clss && (clss->type_op == type_class));
assert(pos >= 0 && pos < get_class_n_supertypes(clss));
return clss->attr.ca.supertypes[pos] = skip_tid(clss->attr.ca.supertypes[pos]);
}
-void set_class_supertype (type *clss, type *supertype, int pos) {
+void set_class_supertype (ir_type *clss, ir_type *supertype, int pos) {
assert(clss && (clss->type_op == type_class));
assert(pos >= 0 && pos < get_class_n_supertypes(clss));
clss->attr.ca.supertypes[pos] = supertype;
}
-void remove_class_supertype(type *clss, type *supertype) {
+void remove_class_supertype(ir_type *clss, ir_type *supertype) {
int i;
assert(clss && (clss->type_op == type_class));
for (i = 0; i < (ARR_LEN (clss->attr.ca.supertypes)); i++)
return "invalid peculiarity";
}
-peculiarity get_class_peculiarity (const type *clss) {
+peculiarity get_class_peculiarity (const ir_type *clss) {
assert(clss && (clss->type_op == type_class));
return clss->attr.ca.peculiarity;
}
-void set_class_peculiarity (type *clss, peculiarity pec) {
+void set_class_peculiarity (ir_type *clss, peculiarity pec) {
assert(clss && (clss->type_op == type_class));
assert(pec != peculiarity_inherited); /* There is no inheritance of types in libFirm. */
clss->attr.ca.peculiarity = pec;
}
-void set_class_dfn (type *clss, int dfn)
+void set_class_dfn (ir_type *clss, int dfn)
{
clss->attr.ca.dfn = dfn;
}
-int get_class_dfn (const type *clss)
+int get_class_dfn (const ir_type *clss)
{
return (clss->attr.ca.dfn);
}
/* typecheck */
-int (is_Class_type)(const type *clss) {
+int (is_Class_type)(const ir_type *clss) {
return _is_class_type(clss);
}
-void set_class_mode(type *tp, ir_mode *mode) {
+void set_class_mode(ir_type *tp, ir_mode *mode) {
/* for classes and structs we allow to set a mode if the layout is fixed AND the size matches */
assert(get_type_state(tp) == layout_fixed &&
tp->size == get_mode_size_bits(mode) && "mode don't match class layout");
tp->mode = mode;
}
-void set_class_size_bits(type *tp, int size) {
+void set_class_size_bits(ir_type *tp, int size) {
/* argh: we must allow to set negative values as "invalid size" */
tp->size = (size >= 0) ? (size + 7) & ~7 : size;
assert(tp->size == size && "setting a bit size is NOT allowed for this type");
/*----------------------------------------------------------------**/
/* create a new type struct */
-type *new_d_type_struct(ident *name, dbg_info *db) {
- type *res = new_type(type_struct, NULL, name, db);
+ir_type *new_d_type_struct(ident *name, dbg_info *db) {
+ ir_type *res = new_type(type_struct, NULL, name, db);
res->attr.sa.members = NEW_ARR_F(entity *, 0);
hook_new_type(res);
return res;
}
-type *new_type_struct (ident *name) {
+ir_type *new_type_struct (ident *name) {
return new_d_type_struct (name, NULL);
}
-void free_struct_entities (type *strct) {
+void free_struct_entities (ir_type *strct) {
int i;
assert(strct && (strct->type_op == type_struct));
for (i = get_struct_n_members(strct)-1; i >= 0; --i)
free_entity(get_struct_member(strct, i));
}
-void free_struct_attrs (type *strct) {
+void free_struct_attrs (ir_type *strct) {
assert(strct && (strct->type_op == type_struct));
DEL_ARR_F(strct->attr.sa.members);
}
/* manipulate private fields of struct */
-int get_struct_n_members (const type *strct) {
+int get_struct_n_members (const ir_type *strct) {
assert(strct && (strct->type_op == type_struct));
return (ARR_LEN (strct->attr.sa.members));
}
-void add_struct_member (type *strct, entity *member) {
+void add_struct_member (ir_type *strct, entity *member) {
assert(strct && (strct->type_op == type_struct));
assert(get_type_tpop(get_entity_type(member)) != type_method);
/* @@@ lowerfirm geht nicht durch */
ARR_APP1 (entity *, strct->attr.sa.members, member);
}
-entity *get_struct_member (const type *strct, int pos) {
+entity *get_struct_member (const ir_type *strct, int pos) {
assert(strct && (strct->type_op == type_struct));
assert(pos >= 0 && pos < get_struct_n_members(strct));
return strct->attr.sa.members[pos];
}
-int get_struct_member_index(type *strct, entity *mem) {
+int get_struct_member_index(ir_type *strct, entity *mem) {
int i;
assert(strct && (strct->type_op == type_struct));
for (i = 0; i < get_struct_n_members(strct); i++)
return -1;
}
-void set_struct_member (type *strct, int pos, entity *member) {
+void set_struct_member (ir_type *strct, int pos, entity *member) {
assert(strct && (strct->type_op == type_struct));
assert(pos >= 0 && pos < get_struct_n_members(strct));
assert(get_entity_type(member)->type_op != type_method);/* @@@ lowerfirm !!*/
strct->attr.sa.members[pos] = member;
}
-void remove_struct_member(type *strct, entity *member) {
+void remove_struct_member(ir_type *strct, entity *member) {
int i;
assert(strct && (strct->type_op == type_struct));
for (i = 0; i < (ARR_LEN (strct->attr.sa.members)); i++)
}
/* typecheck */
-int (is_Struct_type)(const type *strct) {
+int (is_Struct_type)(const ir_type *strct) {
return _is_struct_type(strct);
}
-void set_struct_mode(type *tp, ir_mode *mode) {
+void set_struct_mode(ir_type *tp, ir_mode *mode) {
/* for classes and structs we allow to set a mode if the layout is fixed AND the size matches */
assert(get_type_state(tp) == layout_fixed &&
tp->size == get_mode_size_bits(mode) && "mode don't match struct layout");
tp->mode = mode;
}
-void set_struct_size_bits(type *tp, int size) {
+void set_struct_size_bits(ir_type *tp, int size) {
/* argh: we must allow to set negative values as "invalid size" */
tp->size = (size >= 0) ? (size + 7) & ~7 : size;
assert(tp->size == size && "setting a bit size is NOT allowed for this type");
* @param len number of fields
* @param tps array of field types with length len
*/
-static INLINE type *
+static INLINE ir_type *
build_value_type(ident *name, int len, tp_ent_pair *tps) {
int i;
- type *res = new_type_struct(name);
+ ir_type *res = new_type_struct(name);
/* Remove type from type list. Must be treated differently than other types. */
remove_irp_type(res);
for (i = 0; i < len; i++) {
/* use res as default if corresponding type is not yet set. */
- type *elt_type = tps[i].tp ? tps[i].tp : res;
+ ir_type *elt_type = tps[i].tp ? tps[i].tp : res;
tps[i].ent = new_entity(res, mangle_u(name, get_type_ident(elt_type)), elt_type);
}
/* Create a new method type.
N_param is the number of parameters, n_res the number of results. */
-type *new_d_type_method(ident *name, int n_param, int n_res, dbg_info *db) {
- type *res;
+ir_type *new_d_type_method(ident *name, int n_param, int n_res, dbg_info *db) {
+ ir_type *res;
assert((get_mode_size_bytes(mode_P_code) != -1) && "unorthodox modes not implemented");
res = new_type(type_method, mode_P_code, name, db);
return res;
}
-type *new_type_method(ident *name, int n_param, int n_res) {
+ir_type *new_type_method(ident *name, int n_param, int n_res) {
return new_d_type_method(name, n_param, n_res, NULL);
}
-void free_method_entities(type *method) {
+void free_method_entities(ir_type *method) {
assert(method && (method->type_op == type_method));
}
/* Attention: also frees entities in value parameter subtypes! */
-void free_method_attrs(type *method) {
+void free_method_attrs(ir_type *method) {
assert(method && (method->type_op == type_method));
free(method->attr.ma.param_type);
free(method->attr.ma.res_type);
}
/* manipulate private fields of method. */
-int (get_method_n_params)(const type *method) {
+int (get_method_n_params)(const ir_type *method) {
return _get_method_n_params(method);
}
-type *get_method_param_type(type *method, int pos) {
- type *res;
+ir_type *get_method_param_type(ir_type *method, int pos) {
+ ir_type *res;
assert(method && (method->type_op == type_method));
assert(pos >= 0 && pos < get_method_n_params(method));
res = method->attr.ma.param_type[pos].tp;
return method->attr.ma.param_type[pos].tp = skip_tid(res);
}
-void set_method_param_type(type *method, int pos, type* tp) {
+void set_method_param_type(ir_type *method, int pos, ir_type *tp) {
assert(method && (method->type_op == type_method));
assert(pos >= 0 && pos < get_method_n_params(method));
method->attr.ma.param_type[pos].tp = tp;
/* Returns an entity that represents the copied value argument. Only necessary
for compounds passed by value. */
-entity *get_method_value_param_ent(type *method, int pos) {
+entity *get_method_value_param_ent(ir_type *method, int pos) {
assert(method && (method->type_op == type_method));
assert(pos >= 0 && pos < get_method_n_params(method));
/*
* Returns a type that represents the copied value arguments.
*/
-type *get_method_value_param_type(const type *method)
+ir_type *get_method_value_param_type(const ir_type *method)
{
assert(method && (method->type_op == type_method));
return method->attr.ma.value_params;
}
-int (get_method_n_ress)(const type *method) {
+int (get_method_n_ress)(const ir_type *method) {
return _get_method_n_ress(method);
}
-type *get_method_res_type(type *method, int pos) {
- type *res;
+ir_type *get_method_res_type(ir_type *method, int pos) {
+ ir_type *res;
assert(method && (method->type_op == type_method));
assert(pos >= 0 && pos < get_method_n_ress(method));
res = method->attr.ma.res_type[pos].tp;
return method->attr.ma.res_type[pos].tp = skip_tid(res);
}
-void set_method_res_type(type *method, int pos, type* tp) {
+void set_method_res_type(ir_type *method, int pos, ir_type *tp) {
assert(method && (method->type_op == type_method));
assert(pos >= 0 && pos < get_method_n_ress(method));
- /* set the result type */
+ /* set the result ir_type */
method->attr.ma.res_type[pos].tp = tp;
/* If information constructed set pass-by-value representation. */
if (method->attr.ma.value_ress) {
/* Returns an entity that represents the copied value result. Only necessary
for compounds passed by value. */
-entity *get_method_value_res_ent(type *method, int pos) {
+entity *get_method_value_res_ent(ir_type *method, int pos) {
assert(method && (method->type_op == type_method));
assert(pos >= 0 && pos < get_method_n_ress(method));
/*
* Returns a type that represents the copied value results.
*/
-type *get_method_value_res_type(const type *method) {
+ir_type *get_method_value_res_type(const ir_type *method) {
assert(method && (method->type_op == type_method));
return method->attr.ma.value_ress;
}
#undef X
}
-variadicity get_method_variadicity(const type *method)
+variadicity get_method_variadicity(const ir_type *method)
{
assert(method && (method->type_op == type_method));
return method->attr.ma.variadicity;
}
-void set_method_variadicity(type *method, variadicity vari)
+void set_method_variadicity(ir_type *method, variadicity vari)
{
assert(method && (method->type_op == type_method));
method->attr.ma.variadicity = vari;
* of the method type plus one is returned for variadic functions.
* Non-variadic function types always return -1 here.
*/
-int get_method_first_variadic_param_index(const type *method)
+int get_method_first_variadic_param_index(const ir_type *method)
{
assert(method && (method->type_op == type_method));
* but still have the knowledge, which parameter must be passed as
* variadic one.
*/
-void set_method_first_variadic_param_index(type *method, int index)
+void set_method_first_variadic_param_index(ir_type *method, int index)
{
assert(method && (method->type_op == type_method));
assert(index >= 0 && index <= get_method_n_params(method));
method->attr.ma.first_variadic_param = index;
}
-unsigned (get_method_additional_properties)(const type *method) {
+unsigned (get_method_additional_properties)(const ir_type *method) {
return _get_method_additional_properties(method);
}
-void (set_method_additional_properties)(type *method, unsigned mask) {
+void (set_method_additional_properties)(ir_type *method, unsigned mask) {
_set_method_additional_properties(method, mask);
}
-void (set_method_additional_property)(type *method, mtp_additional_property flag) {
+void (set_method_additional_property)(ir_type *method, mtp_additional_property flag) {
_set_method_additional_property(method, flag);
}
/* Returns the calling convention of an entities graph. */
-unsigned (get_method_calling_convention)(const type *method) {
+unsigned (get_method_calling_convention)(const ir_type *method) {
return _get_method_calling_convention(method);
}
/* Sets the calling convention of an entities graph. */
-void (set_method_calling_convention)(type *method, unsigned cc_mask) {
+void (set_method_calling_convention)(ir_type *method, unsigned cc_mask) {
_set_method_calling_convention(method, cc_mask);
}
/* Returns the number of registers parameters, 0 means default. */
-unsigned get_method_n_regparams(type *method) {
+unsigned get_method_n_regparams(ir_type *method) {
unsigned cc = get_method_calling_convention(method);
assert(IS_FASTCALL(cc));
}
/* Sets the number of registers parameters, 0 means default. */
-void set_method_n_regparams(type *method, unsigned n_regs) {
+void set_method_n_regparams(ir_type *method, unsigned n_regs) {
unsigned cc = get_method_calling_convention(method);
assert(IS_FASTCALL(cc));
}
/* typecheck */
-int (is_Method_type)(const type *method) {
+int (is_Method_type)(const ir_type *method) {
return _is_method_type(method);
}
/*-----------------------------------------------------------------*/
/* create a new type uni */
-type *new_d_type_union(ident *name, dbg_info *db) {
- type *res = new_type(type_union, NULL, name, db);
+ir_type *new_d_type_union(ident *name, dbg_info *db) {
+ ir_type *res = new_type(type_union, NULL, name, db);
res->attr.ua.members = NEW_ARR_F(entity *, 0);
hook_new_type(res);
return new_d_type_union(name, NULL);
}
-void free_union_entities(type *uni) {
+void free_union_entities(ir_type *uni) {
int i;
assert(uni && (uni->type_op == type_union));
for (i = get_union_n_members(uni) - 1; i >= 0; --i)
free_entity(get_union_member(uni, i));
}
-void free_union_attrs (type *uni) {
+void free_union_attrs (ir_type *uni) {
assert(uni && (uni->type_op == type_union));
DEL_ARR_F(uni->attr.ua.members);
}
/* manipulate private fields of union */
-int get_union_n_members (const type *uni) {
+int get_union_n_members (const ir_type *uni) {
assert(uni && (uni->type_op == type_union));
return (ARR_LEN (uni->attr.ua.members));
}
-void add_union_member (type *uni, entity *member) {
+void add_union_member (ir_type *uni, entity *member) {
assert(uni && (uni->type_op == type_union));
assert(uni != get_entity_type(member) && "recursive type");
ARR_APP1 (entity *, uni->attr.ua.members, member);
}
-entity *get_union_member (const type *uni, int pos) {
+entity *get_union_member (const ir_type *uni, int pos) {
assert(uni && (uni->type_op == type_union));
assert(pos >= 0 && pos < get_union_n_members(uni));
return uni->attr.ua.members[pos];
}
-void set_union_member (type *uni, int pos, entity *member) {
+void set_union_member (ir_type *uni, int pos, entity *member) {
assert(uni && (uni->type_op == type_union));
assert(pos >= 0 && pos < get_union_n_members(uni));
uni->attr.ua.members[pos] = member;
}
-void remove_union_member(type *uni, entity *member) {
+void remove_union_member(ir_type *uni, entity *member) {
int i;
assert(uni && (uni->type_op == type_union));
for (i = 0; i < (ARR_LEN (uni->attr.ua.members)); i++)
}
/* typecheck */
-int (is_Union_type)(const type *uni) {
+int (is_Union_type)(const ir_type *uni) {
return _is_union_type(uni);
}
-void set_union_size_bits(type *tp, int size) {
+void set_union_size_bits(ir_type *tp, int size) {
/* argh: we must allow to set negative values as "invalid size" */
tp->size = (size >= 0) ? (size + 7) & ~7 : size;
assert(tp->size == size && "setting a bit size is NOT allowed for this type");
/* create a new type array -- set dimension sizes independently */
-type *new_d_type_array(ident *name, int n_dimensions, type *element_type, dbg_info *db) {
- type *res;
+ir_type *new_d_type_array(ident *name, int n_dimensions, ir_type *element_type, dbg_info *db) {
+ ir_type *res;
int i;
ir_node *unk;
ir_graph *rem = current_ir_graph;
return res;
}
-type *new_type_array(ident *name, int n_dimensions, type *element_type) {
+ir_type *new_type_array(ident *name, int n_dimensions, ir_type *element_type) {
return new_d_type_array(name, n_dimensions, element_type, NULL);
}
-void free_array_automatic_entities(type *array) {
+void free_array_automatic_entities(ir_type *array) {
assert(array && (array->type_op == type_array));
free_entity(get_array_element_entity(array));
}
-void free_array_entities (type *array) {
+void free_array_entities (ir_type *array) {
assert(array && (array->type_op == type_array));
}
-void free_array_attrs (type *array) {
+void free_array_attrs (ir_type *array) {
assert(array && (array->type_op == type_array));
free(array->attr.aa.lower_bound);
free(array->attr.aa.upper_bound);
}
-/* manipulate private fields of array type */
-int get_array_n_dimensions (const type *array) {
+/* manipulate private fields of array ir_type */
+int get_array_n_dimensions (const ir_type *array) {
assert(array && (array->type_op == type_array));
return array->attr.aa.n_dimensions;
}
void
-set_array_bounds (type *array, int dimension, ir_node * lower_bound,
+set_array_bounds (ir_type *array, int dimension, ir_node * lower_bound,
ir_node * upper_bound) {
assert(array && (array->type_op == type_array));
assert(lower_bound && "lower_bound node may not be NULL.");
array->attr.aa.upper_bound[dimension] = upper_bound;
}
void
-set_array_bounds_int (type *array, int dimension, int lower_bound,
+set_array_bounds_int (ir_type *array, int dimension, int lower_bound,
int upper_bound) {
ir_graph *rem = current_ir_graph;
current_ir_graph = get_const_code_irg();
current_ir_graph = rem;
}
void
-set_array_lower_bound (type *array, int dimension, ir_node * lower_bound) {
+set_array_lower_bound (ir_type *array, int dimension, ir_node * lower_bound) {
assert(array && (array->type_op == type_array));
assert(lower_bound && "lower_bound node may not be NULL.");
array->attr.aa.lower_bound[dimension] = lower_bound;
}
-void set_array_lower_bound_int (type *array, int dimension, int lower_bound) {
+void set_array_lower_bound_int (ir_type *array, int dimension, int lower_bound) {
ir_graph *rem = current_ir_graph;
current_ir_graph = get_const_code_irg();
set_array_lower_bound (array, dimension,
current_ir_graph = rem;
}
void
-set_array_upper_bound (type *array, int dimension, ir_node * upper_bound) {
+set_array_upper_bound (ir_type *array, int dimension, ir_node * upper_bound) {
assert(array && (array->type_op == type_array));
assert(upper_bound && "upper_bound node may not be NULL.");
array->attr.aa.upper_bound[dimension] = upper_bound;
}
-void set_array_upper_bound_int (type *array, int dimension, int upper_bound) {
+void set_array_upper_bound_int (ir_type *array, int dimension, int upper_bound) {
ir_graph *rem = current_ir_graph;
current_ir_graph = get_const_code_irg();
set_array_upper_bound (array, dimension,
new_Const(mode_Iu, new_tarval_from_long (upper_bound, mode_Iu)));
current_ir_graph = rem;
}
-int has_array_lower_bound (const type *array, int dimension) {
+int has_array_lower_bound (const ir_type *array, int dimension) {
assert(array && (array->type_op == type_array));
return (get_irn_op(array->attr.aa.lower_bound[dimension]) != op_Unknown);
}
-ir_node *get_array_lower_bound (const type *array, int dimension) {
+ir_node *get_array_lower_bound (const ir_type *array, int dimension) {
assert(array && (array->type_op == type_array));
return array->attr.aa.lower_bound[dimension];
}
-long get_array_lower_bound_int (const type *array, int dimension) {
+long get_array_lower_bound_int (const ir_type *array, int dimension) {
ir_node *node;
assert(array && (array->type_op == type_array));
node = array->attr.aa.lower_bound[dimension];
assert(get_irn_op(node) == op_Const);
return get_tarval_long(get_Const_tarval(node));
}
-int has_array_upper_bound (const type *array, int dimension) {
+int has_array_upper_bound (const ir_type *array, int dimension) {
assert(array && (array->type_op == type_array));
return (get_irn_op(array->attr.aa.upper_bound[dimension]) != op_Unknown);
}
-ir_node * get_array_upper_bound (const type *array, int dimension) {
+ir_node * get_array_upper_bound (const ir_type *array, int dimension) {
assert(array && (array->type_op == type_array));
return array->attr.aa.upper_bound[dimension];
}
-long get_array_upper_bound_int (const type *array, int dimension) {
+long get_array_upper_bound_int (const ir_type *array, int dimension) {
ir_node *node;
assert(array && (array->type_op == type_array));
node = array->attr.aa.upper_bound[dimension];
return get_tarval_long(get_Const_tarval(node));
}
-void set_array_order (type *array, int dimension, int order) {
+void set_array_order (ir_type *array, int dimension, int order) {
assert(array && (array->type_op == type_array));
array->attr.aa.order[dimension] = order;
}
-int get_array_order (const type *array, int dimension) {
+int get_array_order (const ir_type *array, int dimension) {
assert(array && (array->type_op == type_array));
return array->attr.aa.order[dimension];
}
-int find_array_dimension(const type *array, int order) {
+int find_array_dimension(const ir_type *array, int order) {
int dim;
assert(array && (array->type_op == type_array));
return -1;
}
-void set_array_element_type (type *array, type *tp) {
+void set_array_element_type (ir_type *array, ir_type *tp) {
assert(array && (array->type_op == type_array));
assert(!is_Method_type(tp));
array->attr.aa.element_type = tp;
}
-type *get_array_element_type (type *array) {
+ir_type *get_array_element_type (ir_type *array) {
assert(array && (array->type_op == type_array));
return array->attr.aa.element_type = skip_tid(array->attr.aa.element_type);
}
-void set_array_element_entity (type *array, entity *ent) {
+void set_array_element_entity (ir_type *array, entity *ent) {
assert(array && (array->type_op == type_array));
assert((get_entity_type(ent)->type_op != type_method));
array->attr.aa.element_ent = ent;
array->attr.aa.element_type = get_entity_type(ent);
}
-entity *get_array_element_entity (const type *array) {
+entity *get_array_element_entity (const ir_type *array) {
assert(array && (array->type_op == type_array));
return array->attr.aa.element_ent;
}
/* typecheck */
-int (is_Array_type)(const type *array) {
+int (is_Array_type)(const ir_type *array) {
return _is_array_type(array);
}
-void set_array_size_bits(type *tp, int size) {
+void set_array_size_bits(ir_type *tp, int size) {
/* FIXME: Here we should make some checks with the element type size */
tp->size = size;
}
/*-----------------------------------------------------------------*/
/* create a new type enumeration -- set the enumerators independently */
-type *new_d_type_enumeration(ident *name, int n_enums, dbg_info *db) {
- type *res = new_type(type_enumeration, NULL, name, db);
+ir_type *new_d_type_enumeration(ident *name, int n_enums, dbg_info *db) {
+ ir_type *res = new_type(type_enumeration, NULL, name, db);
res->attr.ea.n_enums = n_enums;
res->attr.ea.enumer = xcalloc(n_enums, sizeof(res->attr.ea.enumer[0]));
return res;
}
-type *new_type_enumeration(ident *name, int n_enums) {
+ir_type *new_type_enumeration(ident *name, int n_enums) {
return new_d_type_enumeration(name, n_enums, NULL);
}
-void free_enumeration_entities(type *enumeration) {
+void free_enumeration_entities(ir_type *enumeration) {
assert(enumeration && (enumeration->type_op == type_enumeration));
}
-void free_enumeration_attrs(type *enumeration) {
+void free_enumeration_attrs(ir_type *enumeration) {
assert(enumeration && (enumeration->type_op == type_enumeration));
free(enumeration->attr.ea.enumer);
free(enumeration->attr.ea.enum_nameid);
}
/* manipulate fields of enumeration type. */
-int get_enumeration_n_enums (const type *enumeration) {
+int get_enumeration_n_enums (const ir_type *enumeration) {
assert(enumeration && (enumeration->type_op == type_enumeration));
return enumeration->attr.ea.n_enums;
}
-void set_enumeration_enum (type *enumeration, int pos, tarval *con) {
+void set_enumeration_enum (ir_type *enumeration, int pos, tarval *con) {
assert(enumeration && (enumeration->type_op == type_enumeration));
assert(pos >= 0 && pos < get_enumeration_n_enums(enumeration));
enumeration->attr.ea.enumer[pos] = con;
}
-tarval *get_enumeration_enum (const type *enumeration, int pos) {
+tarval *get_enumeration_enum (const ir_type *enumeration, int pos) {
assert(enumeration && (enumeration->type_op == type_enumeration));
assert(pos >= 0 && pos < get_enumeration_n_enums(enumeration));
return enumeration->attr.ea.enumer[pos];
}
-void set_enumeration_nameid (type *enumeration, int pos, ident *id) {
+void set_enumeration_nameid (ir_type *enumeration, int pos, ident *id) {
assert(enumeration && (enumeration->type_op == type_enumeration));
assert(pos >= 0 && pos < get_enumeration_n_enums(enumeration));
enumeration->attr.ea.enum_nameid[pos] = id;
}
-ident *get_enumeration_nameid (const type *enumeration, int pos) {
+ident *get_enumeration_nameid (const ir_type *enumeration, int pos) {
assert(enumeration && (enumeration->type_op == type_enumeration));
assert(pos >= 0 && pos < get_enumeration_n_enums(enumeration));
return enumeration->attr.ea.enum_nameid[pos];
}
-const char *get_enumeration_name(const type *enumeration, int pos) {
+const char *get_enumeration_name(const ir_type *enumeration, int pos) {
assert(enumeration && (enumeration->type_op == type_enumeration));
assert(pos >= 0 && pos < get_enumeration_n_enums(enumeration));
return get_id_str(enumeration->attr.ea.enum_nameid[pos]);
}
/* typecheck */
-int (is_Enumeration_type)(const type *enumeration) {
+int (is_Enumeration_type)(const ir_type *enumeration) {
return _is_enumeration_type(enumeration);
}
-void set_enumeration_mode(type *tp, ir_mode *mode) {
+void set_enumeration_mode(ir_type *tp, ir_mode *mode) {
assert(mode_is_int(mode) && "Modes of enumerations must be integers");
/* For pointer and enumeration size depends on the mode, but only byte size allowed. */
assert((get_mode_size_bits(mode) & 7) == 0 && "unorthodox modes not implemented");
/*-----------------------------------------------------------------*/
/* Create a new type pointer */
-type *new_d_type_pointer(ident *name, type *points_to, ir_mode *ptr_mode, dbg_info *db) {
- type *res;
+ir_type *new_d_type_pointer(ident *name, ir_type *points_to, ir_mode *ptr_mode, dbg_info *db) {
+ ir_type *res;
assert(mode_is_reference(ptr_mode));
res = new_type(type_pointer, ptr_mode, name, db);
return res;
}
-type *new_type_pointer(ident *name, type *points_to, ir_mode *ptr_mode) {
+ir_type *new_type_pointer(ident *name, ir_type *points_to, ir_mode *ptr_mode) {
return new_d_type_pointer(name, points_to, ptr_mode, NULL);
}
-void free_pointer_entities (type *pointer) {
+void free_pointer_entities (ir_type *pointer) {
assert(pointer && (pointer->type_op == type_pointer));
}
-void free_pointer_attrs (type *pointer) {
+void free_pointer_attrs (ir_type *pointer) {
assert(pointer && (pointer->type_op == type_pointer));
}
/* manipulate fields of type_pointer */
-void set_pointer_points_to_type (type *pointer, type *tp) {
+void set_pointer_points_to_type (ir_type *pointer, ir_type *tp) {
assert(pointer && (pointer->type_op == type_pointer));
pointer->attr.pa.points_to = tp;
}
-type *get_pointer_points_to_type (type *pointer) {
+ir_type *get_pointer_points_to_type (ir_type *pointer) {
assert(pointer && (pointer->type_op == type_pointer));
return pointer->attr.pa.points_to = skip_tid(pointer->attr.pa.points_to);
}
/* typecheck */
-int (is_Pointer_type)(const type *pointer) {
+int (is_Pointer_type)(const ir_type *pointer) {
return _is_pointer_type(pointer);
}
-void set_pointer_mode(type *tp, ir_mode *mode) {
+void set_pointer_mode(ir_type *tp, ir_mode *mode) {
assert(mode_is_reference(mode) && "Modes of pointers must be references");
/* For pointer and enumeration size depends on the mode, but only byte size allowed. */
assert((get_mode_size_bits(mode) & 7) == 0 && "unorthodox modes not implemented");
/* Returns the first pointer type that has as points_to tp.
* Not efficient: O(#types).
* If not found returns firm_unknown_type. */
-type *find_pointer_type_to_type (type *tp) {
+ir_type *find_pointer_type_to_type (ir_type *tp) {
int i;
for (i = 0; i < get_irp_n_types(); ++i) {
- type *found = get_irp_type(i);
+ ir_type *found = get_irp_type(i);
if (is_Pointer_type(found) && get_pointer_points_to_type(found) == tp)
return (found);
}
/*-----------------------------------------------------------------*/
/* create a new type primitive */
-type *new_d_type_primitive(ident *name, ir_mode *mode, dbg_info *db) {
- type *res;
+ir_type *new_d_type_primitive(ident *name, ir_mode *mode, dbg_info *db) {
+ ir_type *res;
/* @@@ assert( mode_is_data(mode) && (!mode_is_reference(mode))); */
res = new_type(type_primitive, mode, name, db);
res->size = get_mode_size_bits(mode);
return res;
}
-type *new_type_primitive(ident *name, ir_mode *mode) {
+ir_type *new_type_primitive(ident *name, ir_mode *mode) {
return new_d_type_primitive(name, mode, NULL);
}
/* typecheck */
-int (is_Primitive_type)(const type *primitive) {
+int (is_Primitive_type)(const ir_type *primitive) {
return _is_primitive_type(primitive);
}
-void set_primitive_mode(type *tp, ir_mode *mode) {
+void set_primitive_mode(ir_type *tp, ir_mode *mode) {
/* Modes of primitives must be data */
assert(mode_is_data(mode));
/*-----------------------------------------------------------------*/
-int (is_atomic_type)(const type *tp) {
+int (is_atomic_type)(const ir_type *tp) {
return _is_atomic_type(tp);
}
/*
* Gets the number of elements in a firm compound type.
*/
-int get_compound_n_members(const type *tp)
+int get_compound_n_members(const ir_type *tp)
{
const tp_op *op = get_type_tpop(tp);
int res = 0;
/*
* Gets the member of a firm compound type at position pos.
*/
-entity *get_compound_member(const type *tp, int pos)
+entity *get_compound_member(const ir_type *tp, int pos)
{
const tp_op *op = get_type_tpop(tp);
entity *res = NULL;
return res;
}
-int is_compound_type(const type *tp) {
+int is_compound_type(const ir_type *tp) {
assert(tp && tp->kind == k_type);
return tp->type_op->flags & TP_OP_FLAG_COMPOUND;
}
-/* Checks, whether a type is a frame type */
-int is_frame_type(const type *tp) {
+/* Checks, whether a type is a frame ir_type */
+int is_frame_type(const ir_type *tp) {
return tp->frame_type;
}
/* Makes a new frame type. */
-type *new_type_frame(ident *name)
+ir_type *new_type_frame(ident *name)
{
- type *res = new_type_class(name);
+ ir_type *res = new_type_class(name);
res->frame_type = 1;
return res;
}
-/* set the type size for the unknown and none type */
-void set_default_size_bits(type *tp, int size) {
+/* set the type size for the unknown and none ir_type */
+void set_default_size_bits(ir_type *tp, int size) {
tp->size = size;
}
* @todo
* mode maybe not global field??
*/
-#ifndef _TYPE_TYPEDEF_
-#define _TYPE_TYPEDEF_
-typedef struct ir_type type;
+#ifndef _IR_TYPE_TYPEDEF_
+#define _IR_TYPE_TYPEDEF_
+typedef struct ir_type ir_type;
#endif
# include "type_or_entity.h"
Does not free array entity.
Warning: make sure these entities are not referenced anywhere else.
*/
-void free_type_entities(type *tp);
+void free_type_entities(ir_type *tp);
/** Frees the memory used by the type.
*
* param subtypes of method types!!! Make sure these are not
* referenced any more. Further make sure there is no pointer type
* that refers to this type. */
-void free_type(type *tp);
+void free_type(ir_type *tp);
-const tp_op*get_type_tpop(const type *tp);
-ident* get_type_tpop_nameid(const type *tp);
-const char* get_type_tpop_name(const type *tp);
-tp_opcode get_type_tpop_code(const type *tp);
+const tp_op*get_type_tpop(const ir_type *tp);
+ident* get_type_tpop_nameid(const ir_type *tp);
+const char* get_type_tpop_name(const ir_type *tp);
+tp_opcode get_type_tpop_code(const ir_type *tp);
-ident* get_type_ident(const type *tp);
-void set_type_ident(type *tp, ident* id);
-const char* get_type_name(const type *tp);
+ident* get_type_ident(const ir_type *tp);
+void set_type_ident(ir_type *tp, ident* id);
+const char* get_type_name(const ir_type *tp);
/** This enumeration flags the visibility of entities and types.
*
* Entities of types are never visibility_external_allocated (right?).
* Else returns visibility_local.
*/
-visibility get_type_visibility (const type *tp);
-void set_type_visibility (type *tp, visibility v);
+visibility get_type_visibility (const ir_type *tp);
+void set_type_visibility (ir_type *tp, visibility v);
const char *get_type_state_name(type_state s);
/** Returns the type layout state of a type. */
-type_state get_type_state(const type *tp);
+type_state get_type_state(const ir_type *tp);
/** Sets the type layout state of a type.
*
* For primitives, pointer and method types the layout is always fixed.
* This call is legal but has no effect.
*/
-void set_type_state(type *tp, type_state state);
+void set_type_state(ir_type *tp, type_state state);
/** Returns the mode of a type.
*
* Returns NULL for all non atomic types.
*/
-ir_mode* get_type_mode(const type *tp);
+ir_mode* get_type_mode(const ir_type *tp);
/** Sets the mode of a type.
*
* Only has an effect on primitive, enumeration and pointer types.
*/
-void set_type_mode(type *tp, ir_mode* m);
+void set_type_mode(ir_type *tp, ir_mode* m);
/** Returns the size of a type in bytes, returns -1 if the size is NOT
* a byte size, i.e. not dividable by 8. */
-int get_type_size_bytes(const type *tp);
+int get_type_size_bytes(const ir_type *tp);
/** Returns the size of a type in bits. */
-int get_type_size_bits(const type *tp);
+int get_type_size_bits(const ir_type *tp);
/** Sets the size of a type in bytes.
*
* For primitive, enumeration, pointer and method types the size
* is always fixed. This call is legal but has no effect.
*/
-void set_type_size_bytes(type *tp, int size);
+void set_type_size_bytes(ir_type *tp, int size);
/** Sets the size of a type in bits.
*
* For primitive, enumeration, pointer and method types the size
* is always fixed. This call is legal but has no effect.
*/
-void set_type_size_bits(type *tp, int size);
+void set_type_size_bits(ir_type *tp, int size);
/** Returns the alignment of a type in bytes.
*
* Returns -1 if the alignment is NOT
* a byte size, i.e. not dividable by 8. Calls get_type_alignment_bits(). */
-int get_type_alignment_bytes(type *tp);
+int get_type_alignment_bytes(ir_type *tp);
/** Returns the alignment of a type in bits.
*
* -#.) method types return 0 here.
* -#.) all other types return 8 here (i.e. aligned at byte).
*/
-int get_type_alignment_bits(type *tp);
+int get_type_alignment_bits(ir_type *tp);
/** Sets the alignment of a type in bytes. */
-void set_type_alignment_bytes(type *tp, int size);
+void set_type_alignment_bytes(ir_type *tp, int size);
/** Sets the alignment of a type in bits.
*
* For method types the alignment is always fixed.
* This call is legal but has no effect.
*/
-void set_type_alignment_bits(type *tp, int size);
+void set_type_alignment_bits(ir_type *tp, int size);
-unsigned long get_type_visited(const type *tp);
-void set_type_visited(type *tp, unsigned long num);
+unsigned long get_type_visited(const ir_type *tp);
+void set_type_visited(ir_type *tp, unsigned long num);
/* Sets visited field in type to type_visited. */
-void mark_type_visited(type *tp);
-int type_visited(const type *tp);
-int type_not_visited(const type *tp);
+void mark_type_visited(ir_type *tp);
+int type_visited(const ir_type *tp);
+int type_not_visited(const ir_type *tp);
/** Returns the associated link field of a type. */
-void* get_type_link(const type *tp);
+void* get_type_link(const ir_type *tp);
/** Sets the associated link field of a type. */
-void set_type_link(type *tp, void *l);
+void set_type_link(ir_type *tp, void *l);
/**
* Visited flag to traverse the type information.
*
* Increase this flag by one before traversing the type information
* using inc_master_type_visited().
- * Mark type nodes as visited by mark_type_visited(type).
- * Check whether node was already visited by type_visited(type)
- * and type_not_visited(type).
+ * Mark type nodes as visited by mark_type_visited(ir_type).
+ * Check whether node was already visited by type_visited(ir_type)
+ * and type_not_visited(ir_type).
* Or use the function to walk all types.
*
* @see typewalk
* @return
* true if the thing is a type, else false
*/
-int is_type (const void *thing);
+int is_type (const void *thing);
/**
* Checks whether two types are structurally equal.
* This is to avoid endless recursions; with pointer types cyclic
* type graphs are possible.)
*/
-int equal_type(type *typ1, type *typ2);
+int equal_type(ir_type *typ1, ir_type *typ2);
/**
* Checks whether two types are structural comparable.
* @return smaller than the points_to type of lt.
*
*/
-int smaller_type (type *st, type *lt);
+int smaller_type (ir_type *st, ir_type *lt);
/**
* @page class_type Representation of a class type
*/
/** Creates a new class type. */
-type *new_type_class (ident *name);
+ir_type *new_type_class (ident *name);
/** Creates a new class type with debug information. */
-type *new_d_type_class (ident *name, dbg_info *db);
+ir_type *new_d_type_class (ident *name, dbg_info *db);
/* --- manipulate private fields of class type --- */
/** Adds the entity as member of the class. */
-void add_class_member (type *clss, entity *member);
+void add_class_member (ir_type *clss, entity *member);
/** Returns the number of members of this class. */
-int get_class_n_members (const type *clss);
+int get_class_n_members (const ir_type *clss);
/** Returns the member at position pos, 0 <= pos < n_member */
-entity *get_class_member (const type *clss, int pos);
+entity *get_class_member (const ir_type *clss, int pos);
/** Returns index of mem in clss, -1 if not contained. */
-int get_class_member_index(type *clss, entity *mem);
+int get_class_member_index(ir_type *clss, entity *mem);
/** Finds the member with name 'name'. If several members with the same
* name returns one of them. Returns NULL if no member found. */
-entity *get_class_member_by_name(type *clss, ident *name);
+entity *get_class_member_by_name(ir_type *clss, ident *name);
/** Overwrites the member at position pos, 0 <= pos < n_member with
* the passed entity. */
-void set_class_member (type *clss, entity *member, int pos);
+void set_class_member (ir_type *clss, entity *member, int pos);
/** Replaces complete member list in class type by the list passed.
*
* Copies the list passed. This function is necessary to reduce the number of members.
* members is an array of entities, num the size of this array. Sets all
* owners of the members passed to clss. */
-void set_class_members (type *clss, entity *members[], int arity);
+void set_class_members (ir_type *clss, entity *members[], int arity);
/** Finds member in the list of members and removes it.
*
* Shrinks the member list, so iterate from the end!!!
* Does not deallocate the entity. */
-void remove_class_member(type *clss, entity *member);
+void remove_class_member(ir_type *clss, entity *member);
/** Adds subtype as subtype to clss.
*
* Checks whether clss is a supertype of subtype. If not
* adds also clss as supertype to subtype. */
-void add_class_subtype (type *clss, type *subtype);
+void add_class_subtype (ir_type *clss, ir_type *subtype);
/** Returns the number of subtypes */
-int get_class_n_subtypes (const type *clss);
+int get_class_n_subtypes (const ir_type *clss);
/** Gets the subtype at position pos, 0 <= pos < n_subtype. */
-type *get_class_subtype (type *clss, int pos);
+ir_type *get_class_subtype (ir_type *clss, int pos);
/** Returns the index to access subclass as subtype of class.
*
* If subclass is no direct subtype of class returns -1.
*/
-int get_class_subtype_index(type *clss, const type *subclass);
+int get_class_subtype_index(ir_type *clss, const ir_type *subclass);
/** Sets the subtype at position pos, 0 <= pos < n_subtype.
*
* Does not set the corresponding supertype relation for subtype: this might
* be a different position! */
-void set_class_subtype (type *clss, type *subtype, int pos);
+void set_class_subtype (ir_type *clss, ir_type *subtype, int pos);
/** Finds subtype in the list of subtypes and removes it */
-void remove_class_subtype(type *clss, type *subtype);
+void remove_class_subtype(ir_type *clss, ir_type *subtype);
/* Convenience macros */
#define add_class_derived_type(clss, drvtype) add_class_subtype(clss, drvtype)
*
* Checks whether clss is a subtype of supertype. If not
* adds also clss as subtype to supertype. */
-void add_class_supertype (type *clss, type *supertype);
+void add_class_supertype (ir_type *clss, ir_type *supertype);
/** Returns the number of supertypes */
-int get_class_n_supertypes (const type *clss);
+int get_class_n_supertypes (const ir_type *clss);
/** Returns the index to access superclass as supertype of class.
*
* If superclass is no direct supertype of class returns -1.
*/
-int get_class_supertype_index(type *clss, type *super_clss);
+int get_class_supertype_index(ir_type *clss, ir_type *super_clss);
/** Gets the supertype at position pos, 0 <= pos < n_supertype. */
-type *get_class_supertype (type *clss, int pos);
+ir_type *get_class_supertype (ir_type *clss, int pos);
/** Sets the supertype at position pos, 0 <= pos < n_supertype.
*
* Does not set the corresponding subtype relation for supertype: this might
* be at a different position! */
-void set_class_supertype (type *clss, type *supertype, int pos);
+void set_class_supertype (ir_type *clss, ir_type *supertype, int pos);
/** Finds supertype in the list of supertypes and removes it */
-void remove_class_supertype(type *clss, type *supertype);
+void remove_class_supertype(ir_type *clss, ir_type *supertype);
/** Convenience macro */
#define add_class_base_type(clss, basetype) add_class_supertype(clss, basetype)
const char *get_peculiarity_string(peculiarity p);
/** Returns the peculiarity of the class. */
-peculiarity get_class_peculiarity (const type *clss);
+peculiarity get_class_peculiarity (const ir_type *clss);
/** Sets the peculiarity of the class. */
-void set_class_peculiarity (type *clss, peculiarity pec);
+void set_class_peculiarity (ir_type *clss, peculiarity pec);
/* Set and get a class' dfn --
@todo This is an undocumented field, subject to change! */
-void set_class_dfn (type *clss, int dfn);
-int get_class_dfn (const type *clss);
+void set_class_dfn (ir_type *clss, int dfn);
+int get_class_dfn (const ir_type *clss);
/** Returns true if a type is a class type. */
-int is_Class_type(const type *clss);
+int is_Class_type(const ir_type *clss);
/**
* @page struct_type Representation of a struct type
* but not shrinked.
*/
/** Creates a new type struct */
-type *new_type_struct (ident *name);
+ir_type *new_type_struct (ident *name);
/** Creates a new type struct with debug information. */
-type *new_d_type_struct (ident *name, dbg_info* db);
+ir_type *new_d_type_struct (ident *name, dbg_info* db);
/* --- manipulate private fields of struct --- */
/** Adds the entity as member of the struct. */
-void add_struct_member (type *strct, entity *member);
+void add_struct_member (ir_type *strct, entity *member);
/** Returns the number of members of this struct. */
-int get_struct_n_members (const type *strct);
+int get_struct_n_members (const ir_type *strct);
/** Returns the member at position pos, 0 <= pos < n_member */
-entity *get_struct_member (const type *strct, int pos);
+entity *get_struct_member (const ir_type *strct, int pos);
/** Returns index of member in strct, -1 if not contained. */
-int get_struct_member_index(type *strct, entity *member);
+int get_struct_member_index(ir_type *strct, entity *member);
/** Overwrites the member at position pos, 0 <= pos < n_member with
the passed entity. */
-void set_struct_member (type *strct, int pos, entity *member);
+void set_struct_member (ir_type *strct, int pos, entity *member);
/** Finds member in the list of members and removes it. */
-void remove_struct_member (type *strct, entity *member);
+void remove_struct_member (ir_type *strct, entity *member);
/** Returns true if a type is a struct type. */
-int is_Struct_type(const type *strct);
+int is_Struct_type(const ir_type *strct);
/**
* @page method_type Representation of a method type
* The arrays for the parameter and result types are not initialized by
* the constructor.
*/
-type *new_type_method (ident *name, int n_param, int n_res);
+ir_type *new_type_method (ident *name, int n_param, int n_res);
/** Create a new method type with debug information.
*
* The arrays for the parameter and result types are not initialized by
* the constructor.
*/
-type *new_d_type_method (ident *name, int n_param, int n_res, dbg_info* db);
+ir_type *new_d_type_method (ident *name, int n_param, int n_res, dbg_info* db);
/* -- manipulate private fields of method. -- */
/** Returns the number of parameters of this method. */
-int get_method_n_params (const type *method);
+int get_method_n_params (const ir_type *method);
/** Returns the type of the parameter at position pos of a method. */
-type *get_method_param_type(type *method, int pos);
+ir_type *get_method_param_type(ir_type *method, int pos);
/** Sets the type of the parameter at position pos of a method.
Also changes the type in the pass-by-value representation by just
changing the type of the corresponding entity if the representation is constructed. */
-void set_method_param_type(type *method, int pos, type* tp);
+void set_method_param_type(ir_type *method, int pos, ir_type *tp);
/** Returns an entity that represents the copied value argument. Only necessary
for compounds passed by value. This information is constructed only on demand. */
-entity *get_method_value_param_ent(type *method, int pos);
+entity *get_method_value_param_ent(ir_type *method, int pos);
/**
* Returns a type that represents the copied value arguments.
*/
-type *get_method_value_param_type(const type *method);
+ir_type *get_method_value_param_type(const ir_type *method);
/** Returns the number of results of a method type. */
-int get_method_n_ress (const type *method);
+int get_method_n_ress (const ir_type *method);
/** Returns the return type of a method type at position pos. */
-type *get_method_res_type(type *method, int pos);
+ir_type *get_method_res_type(ir_type *method, int pos);
/** Sets the type of the result at position pos of a method.
Also changes the type in the pass-by-value representation by just
changing the type of the corresponding entity if the representation is constructed. */
-void set_method_res_type(type *method, int pos, type* tp);
+void set_method_res_type(ir_type *method, int pos, ir_type *tp);
/** Returns an entity that represents the copied value result. Only necessary
for compounds passed by value. This information is constructed only on demand. */
-entity *get_method_value_res_ent(type *method, int pos);
+entity *get_method_value_res_ent(ir_type *method, int pos);
/**
* Returns a type that represents the copied value results.
*/
-type *get_method_value_res_type(const type *method);
+ir_type *get_method_value_res_type(const ir_type *method);
/**
* This enum flags the variadicity of methods (methods with a
const char *get_variadicity_name(variadicity vari);
/** Returns the variadicity of a method. */
-variadicity get_method_variadicity(const type *method);
+variadicity get_method_variadicity(const ir_type *method);
/** Sets the variadicity of a method. */
-void set_method_variadicity(type *method, variadicity vari);
+void set_method_variadicity(ir_type *method, variadicity vari);
/**
* Returns the first variadic parameter index of a type.
* of the method type plus one is returned for variadic functions.
* Non-variadic function types always return -1 here.
*/
-int get_method_first_variadic_param_index(const type *method);
+int get_method_first_variadic_param_index(const ir_type *method);
/**
* Sets the first variadic parameter index. This allows to specify
* but still have the knowledge, which parameter must be passed as
* variadic one.
*/
-void set_method_first_variadic_param_index(type *method, int index);
+void set_method_first_variadic_param_index(ir_type *method, int index);
/**
* additional method type properties:
GCC: __attribute__((naked)). */
mtp_property_malloc = 0x00000020, /**< This method returns newly allocate memory.
GCC: __attribute__((malloc)). */
+ mtp_property_intrinsic = 0x00000040, /**< This method is intrinsic. It is expected that
+ a lowering phase will remove all calls to it. */
mtp_property_inherited = 0x40000000 /**< used only in irg's, means property is inherited
from type. */
} mtp_additional_property;
/** Returns the mask of the additional graph properties. */
-unsigned get_method_additional_properties(const type *method);
+unsigned get_method_additional_properties(const ir_type *method);
/** Sets the mask of the additional graph properties. */
-void set_method_additional_properties(type *method, unsigned property_mask);
+void set_method_additional_properties(ir_type *method, unsigned property_mask);
/** Sets one additional graph property. */
-void set_method_additional_property(type *method, mtp_additional_property flag);
+void set_method_additional_property(ir_type *method, mtp_additional_property flag);
/**
* calling conventions: lower 24 bits are the number of register parameters,
#define SET_FASTCALL(cc_mask) (((cc_mask) & ~cc_bits) | cc_fastcall_set)
/** Returns the calling convention of an entities graph. */
-unsigned get_method_calling_convention(const type *method);
+unsigned get_method_calling_convention(const ir_type *method);
/** Sets the calling convention of an entities graph. */
-void set_method_calling_convention(type *method, unsigned cc_mask);
+void set_method_calling_convention(ir_type *method, unsigned cc_mask);
/** Returns the number of registers parameters, 0 means default. */
-unsigned get_method_n_regparams(type *method);
+unsigned get_method_n_regparams(ir_type *method);
/** Sets the number of registers parameters, 0 means default. */
-void set_method_n_regparams(type *method, unsigned n_regs);
+void set_method_n_regparams(ir_type *method, unsigned n_regs);
/** Returns true if a type is a method type. */
-int is_Method_type (const type *method);
+int is_Method_type (const ir_type *method);
/**
* @page union_type Representation of a union (variant) type.
* but not shrinked.
*/
/** Creates a new type union. */
-type *new_type_union (ident *name);
+ir_type *new_type_union (ident *name);
/** Creates a new type union with debug information. */
-type *new_d_type_union (ident *name, dbg_info* db);
+ir_type *new_d_type_union (ident *name, dbg_info* db);
/* --- manipulate private fields of struct --- */
/** Returns the number of unioned types of this union */
-int get_union_n_members (const type *uni);
+int get_union_n_members (const ir_type *uni);
/** Adds a new entity to a union type */
-void add_union_member (type *uni, entity *member);
+void add_union_member (ir_type *uni, entity *member);
/** Returns the entity at position pos of a union */
-entity *get_union_member (const type *uni, int pos);
+entity *get_union_member (const ir_type *uni, int pos);
/** Overwrites a entity at position pos in a union type. */
-void set_union_member (type *uni, int pos, entity *member);
+void set_union_member (ir_type *uni, int pos, entity *member);
/** Finds member in the list of members and removes it. */
-void remove_union_member (type *uni, entity *member);
+void remove_union_member (ir_type *uni, entity *member);
/** Returns true if a type is a union type. */
-int is_Union_type (const type *uni);
+int is_Union_type (const ir_type *uni);
/**
* @page array_type Representation of an array type
* The entity for array elements is built automatically.
* Set dimension sizes after call to constructor with set_* routines.
*/
-type *new_type_array (ident *name, int n_dimensions,
- type *element_type);
+ir_type *new_type_array (ident *name, int n_dimensions,
+ ir_type *element_type);
/** Create a new type array with debug information.
*
* Set dimension sizes after call to constructor with set_* routines.
* A legal array type must have at least one dimension set.
*/
-type *new_d_type_array (ident *name, int n_dimensions,
- type *element_type, dbg_info* db);
+ir_type *new_d_type_array (ident *name, int n_dimensions,
+ ir_type *element_type, dbg_info* db);
/* --- manipulate private fields of array type --- */
/** Returns the number of array dimensions of this type. */
-int get_array_n_dimensions (const type *array);
+int get_array_n_dimensions (const ir_type *array);
/**
* Allocates Const nodes of mode_I for one array dimension.
* Upper bound in Firm is the element next to the last, i.e. [lower,upper[
*/
-void set_array_bounds_int (type *array, int dimension, int lower_bound,
+void set_array_bounds_int (ir_type *array, int dimension, int lower_bound,
int upper_bound);
/**
* Sets the bounds for one array dimension.
* Upper bound in Firm is the element next to the last, i.e. [lower,upper[
*/
-void set_array_bounds (type *array, int dimension, ir_node *lower_bound,
+void set_array_bounds (ir_type *array, int dimension, ir_node *lower_bound,
ir_node *upper_bound);
/** Sets the lower bound for one array dimension, i.e. [lower,upper[ */
-void set_array_lower_bound (type *array, int dimension, ir_node *lower_bound);
+void set_array_lower_bound (ir_type *array, int dimension, ir_node *lower_bound);
/** Allocates Const nodes of mode_I for the lower bound of an array
dimension, i.e. [lower,upper[ */
-void set_array_lower_bound_int (type *array, int dimension, int lower_bound);
+void set_array_lower_bound_int (ir_type *array, int dimension, int lower_bound);
/** Sets the upper bound for one array dimension, i.e. [lower,upper[ */
-void set_array_upper_bound (type *array, int dimension, ir_node *upper_bound);
+void set_array_upper_bound (ir_type *array, int dimension, ir_node *upper_bound);
/** Allocates Const nodes of mode_I for the upper bound of an array
dimension, i.e. [lower,upper[. */
-void set_array_upper_bound_int (type *array, int dimension, int upper_bound);
+void set_array_upper_bound_int (ir_type *array, int dimension, int upper_bound);
/** Returns true if lower bound != Unknown. */
-int has_array_lower_bound (const type *array, int dimension);
+int has_array_lower_bound (const ir_type *array, int dimension);
/** Returns the lower bound of an array. */
-ir_node * get_array_lower_bound (const type *array, int dimension);
+ir_node * get_array_lower_bound (const ir_type *array, int dimension);
/** Works only if bound is Const node with tarval that can be converted to long. */
-long get_array_lower_bound_int (const type *array, int dimension);
+long get_array_lower_bound_int (const ir_type *array, int dimension);
/** returns true if lower bound != Unknown */
-int has_array_upper_bound (const type *array, int dimension);
+int has_array_upper_bound (const ir_type *array, int dimension);
/** Returns the upper bound of an array. */
-ir_node * get_array_upper_bound (const type *array, int dimension);
+ir_node * get_array_upper_bound (const ir_type *array, int dimension);
/** Works only if bound is Const node with tarval that can be converted to long. */
-long get_array_upper_bound_int (const type *array, int dimension);
+long get_array_upper_bound_int (const ir_type *array, int dimension);
/** Sets an array dimension to a specific order. */
-void set_array_order (type *array, int dimension, int order);
+void set_array_order (ir_type *array, int dimension, int order);
/** Returns the order of an array dimension. */
-int get_array_order (const type *array, int dimension);
+int get_array_order (const ir_type *array, int dimension);
/** Find the array dimension that is placed at order ord. */
-int find_array_dimension(const type *array, int order);
+int find_array_dimension(const ir_type *array, int order);
/** Sets the array element type. */
-void set_array_element_type (type *array, type *tp);
+void set_array_element_type (ir_type *array, ir_type* tp);
/** Gets the array element type. */
-type *get_array_element_type (type *array);
+ir_type *get_array_element_type (ir_type *array);
/** Sets the array element entity. */
-void set_array_element_entity (type *array, entity *ent);
+void set_array_element_entity (ir_type *array, entity *ent);
/** Get the array element entity. */
-entity *get_array_element_entity (const type *array);
+entity *get_array_element_entity (const ir_type *array);
/** Returns true if a type is an array type. */
-int is_Array_type(const type *array);
+int is_Array_type(const ir_type *array);
/**
* @page enumeration_type Representation of an enumeration type
* constants
*/
/** Create a new type enumeration -- set the enumerators independently. */
-type *new_type_enumeration (ident *name, int n_enums);
+ir_type *new_type_enumeration (ident *name, int n_enums);
/** Create a new type enumeration with debug information -- set the enumerators independently. */
-type *new_d_type_enumeration (ident *name, int n_enums, dbg_info* db);
+ir_type *new_d_type_enumeration (ident *name, int n_enums, dbg_info* db);
/* --- manipulate fields of enumeration type. --- */
/** Returns the number of enumeration values of this enumeration */
-int get_enumeration_n_enums (const type *enumeration);
+int get_enumeration_n_enums (const ir_type *enumeration);
/** Sets the enumeration value at a given position. */
-void set_enumeration_enum (type *enumeration, int pos, tarval *con);
+void set_enumeration_enum (ir_type *enumeration, int pos, tarval *con);
/** Returns the enumeration value at a given position. */
-tarval *get_enumeration_enum (const type *enumeration, int pos);
+tarval *get_enumeration_enum (const ir_type *enumeration, int pos);
/** Assign an ident to an enumeration value at a given position. */
-void set_enumeration_nameid (type *enumeration, int pos, ident *id);
+void set_enumeration_nameid (ir_type *enumeration, int pos, ident *id);
/** Returns the assigned ident of an enumeration value at a given position. */
-ident *get_enumeration_nameid (const type *enumeration, int pos);
+ident *get_enumeration_nameid (const ir_type *enumeration, int pos);
/** Returns the assigned name of an enumeration value at a given position. */
-const char *get_enumeration_name(const type *enumeration, int pos);
+const char *get_enumeration_name(const ir_type *enumeration, int pos);
/** Returns true if a type is a enumeration type. */
-int is_Enumeration_type (const type *enumeration);
+int is_Enumeration_type (const ir_type *enumeration);
/**
* @page pointer_type Representation of a pointer type
*/
/** Creates a new type pointer. */
-type *new_type_pointer (ident *name, type *points_to, ir_mode *ptr_mode);
+ir_type *new_type_pointer (ident *name, ir_type *points_to, ir_mode *ptr_mode);
/** Creates a new type pointer with debug information. */
-type *new_d_type_pointer (ident *name, type *points_to, ir_mode *ptr_mode, dbg_info* db);
+ir_type *new_d_type_pointer (ident *name, ir_type *points_to, ir_mode *ptr_mode, dbg_info* db);
/* --- manipulate fields of type_pointer --- */
/** Sets the type to which a pointer points to. */
-void set_pointer_points_to_type (type *pointer, type *tp);
+void set_pointer_points_to_type (ir_type *pointer, ir_type *tp);
/** Returns the type to which a pointer points to. */
-type *get_pointer_points_to_type (type *pointer);
+ir_type *get_pointer_points_to_type (ir_type *pointer);
/** Returns true if a type is a pointer type. */
-int is_Pointer_type (const type *pointer);
+int is_Pointer_type (const ir_type *pointer);
/** Returns the first pointer type that has as points_to tp.
* Not efficient: O(#types).
* If not found returns unknown_type. */
-type *find_pointer_type_to_type (type *tp);
+ir_type *find_pointer_type_to_type (ir_type *tp);
/**
* @page primitive_type Representation of a primitive type
* important information they carry is held in the common mode field.
*/
/** Creates a new primitive type. */
-type *new_type_primitive (ident *name, ir_mode *mode);
+ir_type *new_type_primitive (ident *name, ir_mode *mode);
/** Creates a new primitive type with debug information. */
-type *new_d_type_primitive (ident *name, ir_mode *mode, dbg_info* db);
+ir_type *new_d_type_primitive (ident *name, ir_mode *mode, dbg_info* db);
/** Returns true if a type is a primitive type. */
-int is_Primitive_type (const type *primitive);
+int is_Primitive_type (const ir_type *primitive);
/**
/** A variable that contains the only none type. */
extern type *firm_none_type;
/** Returns the none type */
-type *get_none_type(void);
+ir_type *get_none_type(void);
/**
* @page unknown_type
/** A variable that contains the only unknown type. */
extern type *firm_unknown_type;
/** Returns the unknown type */
-type *get_unknown_type(void);
+ir_type *get_unknown_type(void);
/**
* @param tp any type
* @return true if type is primitive, pointer or enumeration
*/
-int is_atomic_type(const type *tp);
+int is_atomic_type(const ir_type *tp);
/* --- Support for compound types --- */
*
* @return Number of members in the compound type.
*/
-int get_compound_n_members(const type *tp);
+int get_compound_n_members(const ir_type *tp);
/**
* Gets the member of a firm compound type at position pos.
*
* @see get_compound_n_members() for justification of existence.
*/
-entity *get_compound_member(const type *tp, int pos);
+entity *get_compound_member(const ir_type *tp, int pos);
/**
* Checks whether a type is compound.
*
* @return true if the type is class, structure, union or array type.
*/
-int is_compound_type(const type *tp);
+int is_compound_type(const ir_type *tp);
/**
* Checks, whether a type is a frame type
*/
-int is_frame_type(const type *tp);
+int is_frame_type(const ir_type *tp);
/**
* Makes a new frame type. Frame types are class types,
* so all class access functions work.
* Frame types are not in the global list of types.
*/
-type *new_type_frame(ident *name);
+ir_type *new_type_frame(ident *name);
/*-----------------------------------------------------------------*/
/** Debug aides **/
* debugging, (configure with --enable-debug) else returns the address
* of the type cast to long.
*/
-long get_type_nr(const type *tp);
+long get_type_nr(const ir_type *tp);
# endif /* _TYPE_H_ */
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