static const declaration_t *current_function_decl;
static ir_node *current_function_name;
+static ir_node *current_funcsig;
static struct obstack asm_obst;
{
const declaration_t *declaration = get_irg_loc_description(irg, pos);
- warningf(declaration->source_position,
+ warningf(&declaration->source_position,
"variable '%#T' might be used uninitialized",
declaration->type, declaration->symbol);
return new_r_Unknown(irg, mode);
return new_id_from_str(buf);
}
-/**
- * Return the signed integer mode of size bytes.
- *
- * @param size the size
- */
-static ir_mode *get_smode(unsigned size)
-{
- static ir_mode *s_modes[16 + 1] = {0, };
- ir_mode *res;
+static ir_mode *_atomic_modes[ATOMIC_TYPE_LAST+1];
- if (size <= 0 || size > 16)
- return NULL;
-
- res = s_modes[size];
- if (res == NULL) {
- unsigned bits;
- char name[32];
+static ir_mode *mode_int, *mode_uint;
- bits = size * 8;
- snprintf(name, sizeof(name), "i%u", bits);
- res = new_ir_mode(name, irms_int_number, bits, 1, irma_twos_complement,
- bits <= machine_size ? machine_size : bits );
+static ir_node *expression_to_firm(const expression_t *expression);
+static inline ir_mode *get_ir_mode(type_t *type);
- s_modes[size] = res;
+static ir_mode *init_atomic_ir_mode(atomic_type_kind_t kind)
+{
+ unsigned flags = get_atomic_type_flags(kind);
+ unsigned size = get_atomic_type_size(kind);
+ if( (flags & (ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_FLOAT))
+ && !(flags & ATOMIC_TYPE_FLAG_COMPLEX)) {
+ char name[64];
+ mode_sort sort;
+ unsigned bit_size = size * 8;
+ bool is_signed = (flags & ATOMIC_TYPE_FLAG_SIGNED) != 0;
+ mode_arithmetic arithmetic;
+ unsigned modulo_shift;
+
+ if(flags & ATOMIC_TYPE_FLAG_INTEGER) {
+ assert(! (flags & ATOMIC_TYPE_FLAG_FLOAT));
+ snprintf(name, sizeof(name), "i%s%d", is_signed?"":"u", bit_size);
+ sort = irms_int_number;
+ arithmetic = irma_twos_complement;
+ modulo_shift = bit_size < machine_size ? machine_size : bit_size;
+ } else {
+ assert(flags & ATOMIC_TYPE_FLAG_FLOAT);
+ snprintf(name, sizeof(name), "f%d", bit_size);
+ sort = irms_float_number;
+ arithmetic = irma_ieee754;
+ modulo_shift = 0;
+ }
+ return new_ir_mode(name, sort, bit_size, is_signed, arithmetic,
+ modulo_shift);
}
- return res;
-}
-
-/**
- * Return the unsigned integer mode of size bytes.
- *
- * @param size the size
- */
-static ir_mode *get_umode(unsigned size)
-{
- static ir_mode *u_modes[16 + 1] = {0, };
- ir_mode *res;
-
- if (size <= 0 || size > 16)
- return NULL;
- res = u_modes[size];
- if (res == NULL) {
- unsigned bits;
- char name[32];
-
- bits = size * 8;
- snprintf(name, sizeof(name), "u%u", bits);
- res = new_ir_mode(name, irms_int_number, bits, 0, irma_twos_complement,
- bits <= machine_size ? machine_size : bits );
-
- u_modes[size] = res;
- }
- return res;
+ return NULL;
}
/**
- * Return the pointer mode of size bytes.
- *
- * @param size the size
+ * Initialises the atomic modes depending on the machine size.
*/
-static ir_mode *get_ptrmode(unsigned size, char *name)
+static void init_atomic_modes(void)
{
- static ir_mode *p_modes[16 + 1] = {0, };
- ir_mode *res;
-
- if (size <= 0 || size > 16)
- return NULL;
-
- res = p_modes[size];
- if (res == NULL) {
- unsigned bits;
- char buf[32];
-
- bits = size * 8;
- if (name == NULL) {
- snprintf(buf, sizeof(buf), "p%u", bits);
- name = buf;
- }
- res = new_ir_mode(name, irms_reference, bits, 0, irma_twos_complement,
- bits <= machine_size ? machine_size : bits);
-
- p_modes[size] = res;
-
- set_reference_mode_signed_eq(res, get_smode(size));
- set_reference_mode_unsigned_eq(res, get_umode(size));
+ for(int i = 0; i <= ATOMIC_TYPE_LAST; ++i) {
+ _atomic_modes[i] = init_atomic_ir_mode((atomic_type_kind_t) i);
}
- return res;
-}
-
-static ir_mode *_atomic_modes[ATOMIC_TYPE_LAST];
-
-static ir_mode *mode_int, *mode_uint;
-
-static ir_node *expression_to_firm(const expression_t *expression);
-static inline ir_mode *get_ir_mode(type_t *type);
-
-/**
- * Initialises the atomic modes depending on the machine size.
- */
-static void init_atomic_modes(void) {
- unsigned int_size = machine_size < 32 ? 2 : 4;
- unsigned long_size = machine_size < 64 ? 4 : 8;
- unsigned llong_size = machine_size < 32 ? 4 : 8;
-
- /* firm has no real void... */
- _atomic_modes[ATOMIC_TYPE_VOID] = mode_T;
- _atomic_modes[ATOMIC_TYPE_CHAR] = char_is_signed ? get_smode(1) : get_umode(1);
- _atomic_modes[ATOMIC_TYPE_SCHAR] = get_smode(1);
- _atomic_modes[ATOMIC_TYPE_UCHAR] = get_umode(1);
- _atomic_modes[ATOMIC_TYPE_SHORT] = get_smode(2);
- _atomic_modes[ATOMIC_TYPE_USHORT] = get_umode(2);
- _atomic_modes[ATOMIC_TYPE_INT] = get_smode(int_size);
- _atomic_modes[ATOMIC_TYPE_UINT] = get_umode(int_size);
- _atomic_modes[ATOMIC_TYPE_LONG] = get_smode(long_size);
- _atomic_modes[ATOMIC_TYPE_ULONG] = get_umode(long_size);
- _atomic_modes[ATOMIC_TYPE_LONGLONG] = get_smode(llong_size);
- _atomic_modes[ATOMIC_TYPE_ULONGLONG] = get_umode(llong_size);
- _atomic_modes[ATOMIC_TYPE_FLOAT] = mode_F;
- _atomic_modes[ATOMIC_TYPE_DOUBLE] = mode_D;
- _atomic_modes[ATOMIC_TYPE_LONG_DOUBLE] = mode_E;
- _atomic_modes[ATOMIC_TYPE_BOOL] = get_umode(int_size);
-
-#ifdef PROVIDE_COMPLEX
- _atomic_modes[ATOMIC_TYPE_BOOL] = _atomic_modes[ATOMIC_TYPE_INT];
- _atomic_modes[ATOMIC_TYPE_FLOAT_IMAGINARY] = _atomic_modes[ATOMIC_TYPE_FLOAT];
- _atomic_modes[ATOMIC_TYPE_DOUBLE_IMAGINARY] = _atomic_modes[ATOMIC_TYPE_DOUBLE];
- _atomic_modes[ATOMIC_TYPE_LONG_DOUBLE_IMAGINARY] = _atomic_modes[ATOMIC_TYPE_LONG_DOUBLE];
-#endif
-
- /* Hmm, pointers should be machine size */
- set_modeP_data(get_ptrmode(machine_size >> 3, NULL));
- set_modeP_code(get_ptrmode(machine_size >> 3, NULL));
-
mode_int = _atomic_modes[ATOMIC_TYPE_INT];
mode_uint = _atomic_modes[ATOMIC_TYPE_UINT];
-}
-
-static ir_mode *get_atomic_mode(const atomic_type_t* atomic_type)
-{
- ir_mode *res = NULL;
- if ((unsigned)atomic_type->akind < (unsigned)ATOMIC_TYPE_LAST)
- res = _atomic_modes[(unsigned)atomic_type->akind];
- if (res == NULL)
- panic("Encountered unknown atomic type");
- return res;
-}
-
-static unsigned get_atomic_type_size(const atomic_type_t *type)
-{
- switch(type->akind) {
- case ATOMIC_TYPE_CHAR:
- case ATOMIC_TYPE_SCHAR:
- case ATOMIC_TYPE_UCHAR:
- return 1;
-
- case ATOMIC_TYPE_SHORT:
- case ATOMIC_TYPE_USHORT:
- return 2;
-
- case ATOMIC_TYPE_BOOL:
- case ATOMIC_TYPE_INT:
- case ATOMIC_TYPE_UINT:
- return machine_size >> 3;
-
- case ATOMIC_TYPE_LONG:
- case ATOMIC_TYPE_ULONG:
- return machine_size > 16 ? machine_size >> 3 : 4;
- case ATOMIC_TYPE_LONGLONG:
- case ATOMIC_TYPE_ULONGLONG:
- return machine_size > 16 ? 8 : 4;
+ /* there's no real void type in firm */
+ _atomic_modes[ATOMIC_TYPE_VOID] = mode_int;
- case ATOMIC_TYPE_FLOAT:
- return 4;
+ /* initialize pointer modes */
+ char name[64];
+ mode_sort sort = irms_reference;
+ unsigned bit_size = machine_size;
+ bool is_signed = 0;
+ mode_arithmetic arithmetic = irma_twos_complement;
+ unsigned modulo_shift
+ = bit_size < machine_size ? machine_size : bit_size;
- case ATOMIC_TYPE_DOUBLE:
- return 8;
+ snprintf(name, sizeof(name), "p%d", machine_size);
+ ir_mode *ptr_mode = new_ir_mode(name, sort, bit_size, is_signed, arithmetic,
+ modulo_shift);
- case ATOMIC_TYPE_LONG_DOUBLE:
- return 12;
+ set_reference_mode_signed_eq(ptr_mode, _atomic_modes[get_intptr_kind()]);
+ set_reference_mode_unsigned_eq(ptr_mode, _atomic_modes[get_uintptr_kind()]);
- case ATOMIC_TYPE_VOID:
- return 1;
-
- case ATOMIC_TYPE_INVALID:
- case ATOMIC_TYPE_LAST:
- break;
- }
- panic("Trying to determine size of invalid atomic type");
+ /* Hmm, pointers should be machine size */
+ set_modeP_data(ptr_mode);
+ set_modeP_code(ptr_mode);
}
static unsigned get_compound_type_size(compound_type_t *type)
case TYPE_ERROR:
panic("error type occured");
case TYPE_ATOMIC:
- return get_atomic_type_size(&type->atomic);
+ return get_atomic_type_size(type->atomic.akind);
case TYPE_ENUM:
return get_mode_size_bytes(mode_int);
case TYPE_COMPOUND_UNION:
return count;
}
-
static ir_type *create_atomic_type(const atomic_type_t *type)
{
- dbg_info *dbgi = get_dbg_info(&type->type.source_position);
- ir_mode *mode = get_atomic_mode(type);
- ident *id = get_mode_ident(mode);
- ir_type *irtype = new_d_type_primitive(id, mode, dbgi);
+ dbg_info *dbgi = get_dbg_info(&type->base.source_position);
+ atomic_type_kind_t kind = type->akind;
+ ir_mode *mode = _atomic_modes[kind];
+ unsigned alignment = get_atomic_type_alignment(kind);
+ ident *id = get_mode_ident(mode);
+ ir_type *irtype = new_d_type_primitive(id, mode, dbgi);
- /* TODO: this is x86 specific, we should fiddle this into
- * lang_features.h somehow... */
- if(type->akind == ATOMIC_TYPE_LONG_DOUBLE
- || type->akind == ATOMIC_TYPE_DOUBLE
- || type->akind == ATOMIC_TYPE_LONGLONG
- || type->akind == ATOMIC_TYPE_ULONGLONG) {
- set_type_alignment_bytes(irtype, 4);
- }
+ if(type->base.alignment > alignment)
+ alignment = type->base.alignment;
+
+ set_type_alignment_bytes(irtype, alignment);
return irtype;
}
ident *id = unique_ident("functiontype");
int n_parameters = count_parameters(function_type);
int n_results = return_type == type_void ? 0 : 1;
- dbg_info *dbgi = get_dbg_info(&function_type->type.source_position);
+ dbg_info *dbgi = get_dbg_info(&function_type->base.source_position);
ir_type *irtype = new_d_type_method(id, n_parameters, n_results, dbgi);
if(return_type != type_void) {
* again (might be a struct). We therefore first create a void* pointer
* and then set the real points_to type
*/
- dbg_info *dbgi = get_dbg_info(&type->type.source_position);
- ir_type *ir_type = new_d_type_pointer(unique_ident("pointer"),
+ dbg_info *dbgi = get_dbg_info(&type->base.source_position);
+ ir_type *ir_type = new_d_type_pointer(unique_ident("pointer"),
ir_type_void, mode_P_data, dbgi);
- type->type.firm_type = ir_type;
+ type->base.firm_type = ir_type;
ir_points_to = get_ir_type(points_to);
set_pointer_points_to_type(ir_type, ir_points_to);
ir_type *ir_element_type = get_ir_type(element_type);
ident *id = unique_ident("array");
- dbg_info *dbgi = get_dbg_info(&type->type.source_position);
+ dbg_info *dbgi = get_dbg_info(&type->base.source_position);
ir_type *ir_type = new_d_type_array(id, 1, ir_element_type, dbgi);
const int align = get_type_alignment_bytes(ir_element_type);
static ir_type *create_bitfield_type(bitfield_type_t *const type)
{
- type_t *base = skip_typeref(type->base);
+ type_t *base = skip_typeref(type->base_type);
assert(base->kind == TYPE_ATOMIC);
ir_type *irbase = get_ir_type(base);
} else {
id = unique_ident("__anonymous_struct");
}
- dbg_info *dbgi = get_dbg_info(&type->type.source_position);
+ dbg_info *dbgi = get_dbg_info(&type->base.source_position);
irtype = new_d_type_struct(id, dbgi);
declaration->v.irtype = irtype;
- type->type.firm_type = irtype;
+ type->base.firm_type = irtype;
} else {
offset = *outer_offset;
align_all = *outer_align;
ir_type *base_irtype;
if(entry_type->kind == TYPE_BITFIELD) {
- base_irtype = get_ir_type(entry_type->bitfield.base);
+ base_irtype = get_ir_type(entry_type->bitfield.base_type);
} else {
base_irtype = get_ir_type(entry_type);
}
} else {
id = unique_ident("__anonymous_union");
}
- dbg_info *dbgi = get_dbg_info(&type->type.source_position);
+ dbg_info *dbgi = get_dbg_info(&type->base.source_position);
irtype = new_d_type_union(id, dbgi);
declaration->v.irtype = irtype;
- type->type.firm_type = irtype;
+ type->base.firm_type = irtype;
} else {
offset = *outer_offset;
align_all = *outer_align;
}
- type->type.firm_type = irtype;
+ type->base.firm_type = irtype;
declaration_t *entry = declaration->scope.declarations;
for( ; entry != NULL; entry = entry->next) {
static ir_type *create_enum_type(enum_type_t *const type)
{
- type->type.firm_type = ir_type_int;
+ type->base.firm_type = ir_type_int;
ir_mode *const mode = mode_int;
tarval *const one = get_mode_one(mode);
return create_symconst(dbgi, mode_P_data, entity);
}
-static ir_node *deref_address(ir_type *const irtype, ir_node *const addr,
+static ir_node *deref_address(type_t *const type, ir_node *const addr,
dbg_info *const dbgi)
{
- if (is_compound_type(irtype) ||
- is_Method_type(irtype) ||
- is_Array_type(irtype)) {
+ ir_type *irtype = get_ir_type(type);
+ if (is_compound_type(irtype)
+ || is_Method_type(irtype)
+ || is_Array_type(irtype)) {
return addr;
}
ir_node *const load = new_d_Load(dbgi, memory, addr, mode);
ir_node *const load_mem = new_d_Proj(dbgi, load, mode_M, pn_Load_M);
ir_node *const load_res = new_d_Proj(dbgi, load, mode, pn_Load_res);
+
+ if(type->base.qualifiers & TYPE_QUALIFIER_VOLATILE) {
+ set_Load_volatility(load, volatility_is_volatile);
+ }
+
set_store(load_mem);
return load_res;
}
}
case DECLARATION_KIND_GLOBAL_VARIABLE: {
ir_node *const addr = get_global_var_address(dbgi, declaration);
- ir_type *const irtype = get_entity_type(declaration->v.entity);
- return deref_address(irtype, addr, dbgi);
+ return deref_address(declaration->type, addr, dbgi);
}
case DECLARATION_KIND_LOCAL_VARIABLE_ENTITY: {
ir_entity *entity = declaration->v.entity;
ir_node *frame = get_local_frame(entity);
ir_node *sel = new_d_simpleSel(dbgi, new_NoMem(), frame, entity);
- ir_type *irtype = get_entity_type(entity);
- return deref_address(irtype, sel, dbgi);
+ return deref_address(declaration->type, sel, dbgi);
}
case DECLARATION_KIND_VARIABLE_LENGTH_ARRAY:
if(is_type_scalar(type)) {
ir_node *store = new_d_Store(dbgi, memory, addr, value);
ir_node *store_mem = new_d_Proj(dbgi, store, mode_M, pn_Store_M);
+ if(type->base.qualifiers & TYPE_QUALIFIER_VOLATILE)
+ set_Store_volatility(store, volatility_is_volatile);
set_store(store_mem);
} else {
ir_type *irtype = get_ir_type(type);
assert(select->kind == EXPR_SELECT);
type_t *type = select->base.type;
assert(type->kind == TYPE_BITFIELD);
- ir_mode *mode = get_ir_mode(type->bitfield.base);
+ ir_mode *mode = get_ir_mode(type->bitfield.base_type);
ir_node *addr = expression_to_addr(select);
assert(get_irn_mode(value) == mode);
ir_node *store = new_d_Store(dbgi, load_mem, addr, new_val);
ir_node *store_mem = new_d_Proj(dbgi, store, mode_M, pn_Store_M);
set_store(store_mem);
+
+ if(type->base.qualifiers & TYPE_QUALIFIER_VOLATILE) {
+ set_Load_volatility(load, volatility_is_volatile);
+ set_Store_volatility(store, volatility_is_volatile);
+ }
}
static void set_value_for_expression(const expression_t *expression,
type_t *type = select->base.type;
assert(type->kind == TYPE_BITFIELD);
- ir_mode *mode = get_ir_mode(type->bitfield.base);
+ ir_mode *mode = get_ir_mode(type->bitfield.base_type);
dbg_info *dbgi = get_dbg_info(&expression->base.source_position);
ir_node *addr = expression_to_addr(select);
ir_node *mem = get_store();
case EXPR_UNARY_DEREFERENCE: {
ir_node *value_node = expression_to_firm(value);
type_t *value_type = skip_typeref(value->base.type);
- ir_type *irtype = get_ir_type(value_type);
- assert(is_Pointer_type(irtype));
- ir_type *points_to = get_pointer_points_to_type(irtype);
+ assert(is_type_pointer(value_type));
+ type_t *points_to = value_type->pointer.points_to;
return deref_address(points_to, value_node, dbgi);
}
case EXPR_UNARY_POSTFIX_INCREMENT:
node = do_strict_conv(dbgi, node);
return node;
} else {
+ /* make sure firm type is constructed */
+ (void) get_ir_type(type);
return value_node;
}
}
type_t *type = revert_automatic_type_conversion(
(const expression_t*) expression);
type = skip_typeref(type);
- ir_type *irtype = get_ir_type(type);
- return deref_address(irtype, addr, dbgi);
+ return deref_address(type, addr, dbgi);
}
static long get_offsetof_offset(const offsetof_expression_t *expression)
type_t *type = revert_automatic_type_conversion(
(const expression_t*) expression);
type = skip_typeref(type);
- ir_type *irtype = get_ir_type(type);
- return deref_address(irtype, addr, dbgi);
+ return deref_address(type, addr, dbgi);
}
/* Values returned by __builtin_classify_type. */
static ir_node *classify_type_to_firm(const classify_type_expression_t *const expr)
{
- const type_t *const type = expr->type_expression->base.type;
+ const type_t *const type = skip_typeref(expr->type_expression->base.type);
gcc_type_class tc;
switch (type->kind)
{
case TYPE_ATOMIC: {
const atomic_type_t *const atomic_type = &type->atomic;
- switch (atomic_type->akind) {
+ switch ((atomic_type_kind_t) atomic_type->akind) {
/* should not be reached */
case ATOMIC_TYPE_INVALID:
tc = no_type_class;
- break;
+ goto make_const;
/* gcc cannot do that */
case ATOMIC_TYPE_VOID:
tc = void_type_class;
- break;
+ goto make_const;
case ATOMIC_TYPE_CHAR: /* gcc handles this as integer */
case ATOMIC_TYPE_SCHAR: /* gcc handles this as integer */
case ATOMIC_TYPE_ULONGLONG:
case ATOMIC_TYPE_BOOL: /* gcc handles this as integer */
tc = integer_type_class;
- break;
+ goto make_const;
case ATOMIC_TYPE_FLOAT:
case ATOMIC_TYPE_DOUBLE:
case ATOMIC_TYPE_LONG_DOUBLE:
tc = real_type_class;
- break;
+ goto make_const;
-#ifdef PROVIDE_COMPLEX
case ATOMIC_TYPE_FLOAT_COMPLEX:
case ATOMIC_TYPE_DOUBLE_COMPLEX:
case ATOMIC_TYPE_LONG_DOUBLE_COMPLEX:
tc = complex_type_class;
- break;
+ goto make_const;
case ATOMIC_TYPE_FLOAT_IMAGINARY:
case ATOMIC_TYPE_DOUBLE_IMAGINARY:
case ATOMIC_TYPE_LONG_DOUBLE_IMAGINARY:
tc = complex_type_class;
- break;
-#endif
-
- default:
- panic("Unimplemented case in classify_type_to_firm().");
+ goto make_const;
}
- break;
+ panic("Unexpected atomic type in classify_type_to_firm().");
}
+ case TYPE_BITFIELD: tc = integer_type_class; goto make_const;
case TYPE_ARRAY: /* gcc handles this as pointer */
case TYPE_FUNCTION: /* gcc handles this as pointer */
- case TYPE_POINTER: tc = pointer_type_class; break;
- case TYPE_COMPOUND_STRUCT: tc = record_type_class; break;
- case TYPE_COMPOUND_UNION: tc = union_type_class; break;
+ case TYPE_POINTER: tc = pointer_type_class; goto make_const;
+ case TYPE_COMPOUND_STRUCT: tc = record_type_class; goto make_const;
+ case TYPE_COMPOUND_UNION: tc = union_type_class; goto make_const;
/* gcc handles this as integer */
- case TYPE_ENUM: tc = integer_type_class; break;
-
- default:
- panic("Unimplemented case in classify_type_to_firm().");
+ case TYPE_ENUM: tc = integer_type_class; goto make_const;
+
+ case TYPE_BUILTIN:
+ /* typedef/typeof should be skipped already */
+ case TYPE_TYPEDEF:
+ case TYPE_TYPEOF:
+ case TYPE_INVALID:
+ case TYPE_ERROR:
+ break;
}
+ panic("unexpected TYPE classify_type_to_firm().");
+make_const: ;
dbg_info *const dbgi = get_dbg_info(&expr->base.source_position);
ir_mode *const mode = mode_int;
tarval *const tv = new_tarval_from_long(tc, mode);
}
static ir_node *function_name_to_firm(
- const string_literal_expression_t *const expr)
-{
- if (current_function_name == NULL) {
- const source_position_t *const src_pos = &expr->base.source_position;
- const char *const name = current_function_decl->symbol->string;
- const string_t string = { name, strlen(name) + 1 };
- current_function_name = string_to_firm(src_pos, "__func__", &string);
+ const funcname_expression_t *const expr)
+{
+ switch(expr->kind) {
+ case FUNCNAME_FUNCTION:
+ case FUNCNAME_PRETTY_FUNCTION:
+ case FUNCNAME_FUNCDNAME:
+ if (current_function_name == NULL) {
+ const source_position_t *const src_pos = &expr->base.source_position;
+ const char *const name = current_function_decl->symbol->string;
+ const string_t string = { name, strlen(name) + 1 };
+ current_function_name = string_to_firm(src_pos, "__func__", &string);
+ }
+ return current_function_name;
+ case FUNCNAME_FUNCSIG:
+ if (current_funcsig == NULL) {
+ const source_position_t *const src_pos = &expr->base.source_position;
+ ir_entity *ent = get_irg_entity(current_ir_graph);
+ const char *const name = get_entity_ld_name(ent);
+ const string_t string = { name, strlen(name) + 1 };
+ current_funcsig = string_to_firm(src_pos, "__FUNCSIG__", &string);
+ }
+ return current_funcsig;
}
-
- return current_function_name;
+ panic("Unsupported function name");
}
static ir_node *statement_expression_to_firm(const statement_expression_t *expr)
static ir_node *va_arg_expression_to_firm(const va_arg_expression_t *const expr)
{
- ir_type *const irtype = get_ir_type(expr->base.type);
+ type_t *const type = expr->base.type;
ir_node *const ap = expression_to_firm(expr->ap);
dbg_info *const dbgi = get_dbg_info(&expr->base.source_position);
- ir_node *const res = deref_address(irtype, ap, dbgi);
+ ir_node *const res = deref_address(type, ap, dbgi);
- ir_node *const cnst = get_type_size(expr->base.type);
- ir_node *const add = new_d_Add(dbgi, ap, cnst, mode_P_data);
+ ir_node *const cnst = get_type_size(expr->base.type);
+ ir_node *const add = new_d_Add(dbgi, ap, cnst, mode_P_data);
set_value_for_expression(expr->ap, add);
return res;
return select_to_firm(&expression->select);
case EXPR_CLASSIFY_TYPE:
return classify_type_to_firm(&expression->classify_type);
- case EXPR_FUNCTION:
- case EXPR_PRETTY_FUNCTION:
- return function_name_to_firm(&expression->string);
+ case EXPR_FUNCNAME:
+ return function_name_to_firm(&expression->funcname);
case EXPR_STATEMENT:
return statement_expression_to_firm(&expression->statement);
case EXPR_VA_START:
ir_type *parent_type)
{
ident *const id = new_id_from_str(declaration->symbol->string);
- ir_type *const irtype = get_ir_type(declaration->type);
+ type_t *const type = skip_typeref(declaration->type);
+ ir_type *const irtype = get_ir_type(type);
dbg_info *const dbgi = get_dbg_info(&declaration->source_position);
ir_entity *const entity = new_d_entity(parent_type, id, irtype, dbgi);
set_entity_ld_ident(entity, id);
set_entity_allocation(entity, allocation_automatic);
else if(declaration_kind == DECLARATION_KIND_GLOBAL_VARIABLE)
set_entity_allocation(entity, allocation_static);
- /* TODO: visibility? */
+
+ if(type->base.qualifiers & TYPE_QUALIFIER_VOLATILE) {
+ set_entity_volatility(entity, volatility_is_volatile);
+ }
}
if(is_type_compound(type)) {
fprintf(stderr, ".%s", entry->compound_entry->symbol->string);
} else if(is_type_array(type)) {
- fprintf(stderr, "[%u]", entry->index);
+ fprintf(stderr, "[%zd]", entry->index);
} else {
fprintf(stderr, "-INVALID-");
}
static ir_initializer_t *create_ir_initializer_string(
const initializer_string_t *initializer, type_t *type)
{
+ type = skip_typeref(type);
+
size_t string_len = initializer->string.size;
assert(type->kind == TYPE_ARRAY && type->array.size_constant);
size_t len = type->array.size;
panic("unknown initializer");
}
+static void create_dynamic_null_initializer(ir_type *type, dbg_info *dbgi,
+ ir_node *base_addr)
+{
+ ir_mode *mode = get_type_mode(type);
+ tarval *zero = get_mode_null(mode);
+ ir_node *cnst = new_d_Const(dbgi, mode, zero);
+
+ /* TODO: bitfields */
+ ir_node *mem = get_store();
+ ir_node *store = new_d_Store(dbgi, mem, base_addr, cnst);
+ ir_node *proj_m = new_Proj(store, mode_M, pn_Store_M);
+ set_store(proj_m);
+}
+
static void create_dynamic_initializer_sub(ir_initializer_t *initializer,
ir_type *type, dbg_info *dbgi, ir_node *base_addr)
{
switch(get_initializer_kind(initializer)) {
case IR_INITIALIZER_NULL: {
- ir_mode *mode = get_type_mode(type);
/* TODO: implement this for compound types... */
assert(type != NULL);
+
+ ir_mode *mode = get_type_mode(type);
tarval *zero = get_mode_null(mode);
ir_node *cnst = new_d_Const(dbgi, mode, zero);
return;
} else if(is_type_array(type) || is_type_compound(type)) {
needs_entity = true;
+ } else if(type->base.qualifiers & TYPE_QUALIFIER_VOLATILE) {
+ needs_entity = true;
}
if(needs_entity) {
ir_entity *const entity = new_d_entity(global_type, id, irtype, dbgi);
set_entity_ld_ident(entity, id);
+ if(type->base.qualifiers & TYPE_QUALIFIER_VOLATILE) {
+ set_entity_volatility(entity, volatility_is_volatile);
+ }
+
declaration->declaration_kind = DECLARATION_KIND_GLOBAL_VARIABLE;
declaration->v.entity = entity;
set_entity_variability(entity, variability_uninitialized);
#endif
}
+static void ms_try_statement_to_firm(ms_try_statement_t *statement) {
+ statement_to_firm(statement->try_statement);
+ warningf(&statement->base.source_position, "structured exception handling ignored");
+}
+
+static void leave_statement_to_firm(leave_statement_t *statement) {
+ errorf(&statement->base.source_position, "__leave not supported yet");
+}
+
static void statement_to_firm(statement_t *statement)
{
switch(statement->kind) {
case STATEMENT_INVALID:
panic("invalid statement found");
+ return;
+ case STATEMENT_EMPTY:
+ /* nothing */
+ return;
case STATEMENT_COMPOUND:
compound_statement_to_firm(&statement->compound);
return;
case STATEMENT_ASM:
asm_statement_to_firm(&statement->asms);
return;
+ case STATEMENT_MS_TRY:
+ ms_try_statement_to_firm(&statement->ms_try);
+ return;
+ case STATEMENT_LEAVE:
+ leave_statement_to_firm(&statement->leave);
+ return;
}
panic("Statement not implemented\n");
}
}
static int count_decls_in_expression(const expression_t *expression) {
+ int count = 0;
+
if(expression == NULL)
return 0;
- switch(expression->base.kind) {
+ switch((expression_kind_t) expression->base.kind) {
case EXPR_STATEMENT:
return count_decls_in_stmts(expression->statement.statement);
EXPR_BINARY_CASES {
EXPR_UNARY_CASES
return count_decls_in_expression(expression->unary.value);
case EXPR_CALL: {
- int count = 0;
call_argument_t *argument = expression->call.arguments;
for( ; argument != NULL; argument = argument->next) {
count += count_decls_in_expression(argument->expression);
return count;
}
- default:
+ case EXPR_UNKNOWN:
+ case EXPR_INVALID:
+ panic("unexpected expression kind");
+
+ case EXPR_COMPOUND_LITERAL:
+ /* TODO... */
+ break;
+
+ case EXPR_CONDITIONAL:
+ count += count_decls_in_expression(expression->conditional.condition);
+ count += count_decls_in_expression(expression->conditional.true_expression);
+ count += count_decls_in_expression(expression->conditional.false_expression);
+ return count;
+
+ case EXPR_BUILTIN_PREFETCH:
+ count += count_decls_in_expression(expression->builtin_prefetch.adr);
+ count += count_decls_in_expression(expression->builtin_prefetch.rw);
+ count += count_decls_in_expression(expression->builtin_prefetch.locality);
+ return count;
+
+ case EXPR_BUILTIN_CONSTANT_P:
+ count += count_decls_in_expression(expression->builtin_constant.value);
+ return count;
+
+ case EXPR_SELECT:
+ count += count_decls_in_expression(expression->select.compound);
+ return count;
+
+ case EXPR_ARRAY_ACCESS:
+ count += count_decls_in_expression(expression->array_access.array_ref);
+ count += count_decls_in_expression(expression->array_access.index);
+ return count;
+
+ case EXPR_CLASSIFY_TYPE:
+ count += count_decls_in_expression(expression->classify_type.type_expression);
+ return count;
+
+ case EXPR_SIZEOF:
+ case EXPR_ALIGNOF: {
+ expression_t *tp_expression = expression->typeprop.tp_expression;
+ if (tp_expression != NULL) {
+ count += count_decls_in_expression(tp_expression);
+ }
+ return count;
+ }
+
+ case EXPR_OFFSETOF:
+ case EXPR_REFERENCE:
+ case EXPR_CONST:
+ case EXPR_CHARACTER_CONSTANT:
+ case EXPR_WIDE_CHARACTER_CONSTANT:
+ case EXPR_STRING_LITERAL:
+ case EXPR_WIDE_STRING_LITERAL:
+ case EXPR_FUNCNAME:
+ case EXPR_BUILTIN_SYMBOL:
+ case EXPR_VA_START:
+ case EXPR_VA_ARG:
break;
}
int count = 0;
for (; stmt != NULL; stmt = stmt->base.next) {
switch (stmt->kind) {
+ case STATEMENT_EMPTY:
+ break;
+
case STATEMENT_DECLARATION: {
const declaration_statement_t *const decl_stmt = &stmt->declaration;
count += count_local_declarations(decl_stmt->declarations_begin,
}
case STATEMENT_GOTO:
+ case STATEMENT_LEAVE:
case STATEMENT_INVALID:
break;
count += count_decls_in_expression(ret_stmt->value);
break;
}
+
+ case STATEMENT_MS_TRY: {
+ const ms_try_statement_t *const try_stmt = &stmt->ms_try;
+ count += count_decls_in_stmts(try_stmt->try_statement);
+ if(try_stmt->except_expression != NULL)
+ count += count_decls_in_expression(try_stmt->except_expression);
+ count += count_decls_in_stmts(try_stmt->final_statement);
+ break;
+ }
}
}
return count;
current_function_decl = declaration;
current_function_name = NULL;
+ current_funcsig = NULL;
assert(imature_blocks == NULL);
imature_blocks = NEW_ARR_F(ir_node*, 0);
ir_type_int = get_ir_type(type_int);
ir_type_const_char = get_ir_type(type_const_char);
ir_type_wchar_t = get_ir_type(type_wchar_t);
- ir_type_void = get_ir_type(type_int); /* we don't have a real void
- type in firm */
-
- type_void->base.firm_type = ir_type_void;
+ ir_type_void = get_ir_type(type_void);
}
void exit_ast2firm(void)