/*
* This file is part of cparser.
- * Copyright (C) 2007-2009 Matthias Braun <matze@braunis.de>
- *
- * This program is free software; you can redistribute it and/or
- * modify it under the terms of the GNU General Public License
- * as published by the Free Software Foundation; either version 2
- * of the License, or (at your option) any later version.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- *
- * You should have received a copy of the GNU General Public License
- * along with this program; if not, write to the Free Software
- * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
- * 02111-1307, USA.
+ * Copyright (C) 2012 Matthias Braun <matze@braunis.de>
*/
#include <config.h>
#include "warning.h"
#include "diagnostic.h"
#include "printer.h"
+#include "separator_t.h"
/** The default calling convention. */
cc_kind_t default_calling_convention = CC_CDECL;
{
static const size_t sizes[] = {
[TYPE_ATOMIC] = sizeof(atomic_type_t),
- [TYPE_COMPLEX] = sizeof(complex_type_t),
- [TYPE_IMAGINARY] = sizeof(imaginary_type_t),
+ [TYPE_IMAGINARY] = sizeof(atomic_type_t),
+ [TYPE_COMPLEX] = sizeof(atomic_type_t),
[TYPE_COMPOUND_STRUCT] = sizeof(compound_type_t),
[TYPE_COMPOUND_UNION] = sizeof(compound_type_t),
[TYPE_ENUM] = sizeof(enum_type_t),
[TYPE_TYPEDEF] = sizeof(typedef_type_t),
[TYPE_TYPEOF] = sizeof(typeof_type_t),
};
- assert(lengthof(sizes) == (int)TYPE_TYPEOF + 1);
- assert(kind <= TYPE_TYPEOF);
+ assert((size_t)kind < lengthof(sizes));
assert(sizes[kind] != 0);
return sizes[kind];
}
*/
atomic_type_properties_t atomic_type_properties[ATOMIC_TYPE_LAST+1] = {
[ATOMIC_TYPE_VOID] = {
- .size = 0,
- .alignment = 0,
- .flags = ATOMIC_TYPE_FLAG_NONE
+ .size = 1,
+ .alignment = 1,
+ .flags = ATOMIC_TYPE_FLAG_NONE,
+ .rank = 0,
},
- [ATOMIC_TYPE_WCHAR_T] = {
- .size = (unsigned)-1,
- .alignment = (unsigned)-1,
- .flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC,
+ [ATOMIC_TYPE_BOOL] = {
+ .size = 1,
+ .alignment = 1,
+ .flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC,
+ .rank = 1,
},
[ATOMIC_TYPE_CHAR] = {
.size = 1,
.alignment = 1,
.flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC,
+ .rank = 2,
},
[ATOMIC_TYPE_SCHAR] = {
.size = 1,
.alignment = 1,
.flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC
| ATOMIC_TYPE_FLAG_SIGNED,
+ .rank = 2,
},
[ATOMIC_TYPE_UCHAR] = {
.size = 1,
.alignment = 1,
.flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC,
+ .rank = 2,
},
[ATOMIC_TYPE_SHORT] = {
.size = 2,
.alignment = 2,
.flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC
- | ATOMIC_TYPE_FLAG_SIGNED
+ | ATOMIC_TYPE_FLAG_SIGNED,
+ .rank = 3,
},
[ATOMIC_TYPE_USHORT] = {
.size = 2,
.alignment = 2,
.flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC,
+ .rank = 3,
},
[ATOMIC_TYPE_INT] = {
.size = (unsigned) -1,
.alignment = (unsigned) -1,
.flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC
| ATOMIC_TYPE_FLAG_SIGNED,
+ .rank = 4,
},
[ATOMIC_TYPE_UINT] = {
.size = (unsigned) -1,
.alignment = (unsigned) -1,
.flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC,
+ .rank = 4,
},
[ATOMIC_TYPE_LONG] = {
.size = (unsigned) -1,
.alignment = (unsigned) -1,
.flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC
| ATOMIC_TYPE_FLAG_SIGNED,
+ .rank = 5,
},
[ATOMIC_TYPE_ULONG] = {
.size = (unsigned) -1,
.alignment = (unsigned) -1,
.flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC,
+ .rank = 5,
},
- [ATOMIC_TYPE_BOOL] = {
- .size = 1,
- .alignment = 1,
+ [ATOMIC_TYPE_LONGLONG] = {
+ .size = 8,
+ .alignment = 8,
+ .flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC
+ | ATOMIC_TYPE_FLAG_SIGNED,
+ .rank = 6,
+ },
+ [ATOMIC_TYPE_ULONGLONG] = {
+ .size = 8,
+ .alignment = 8,
.flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC,
+ .rank = 6,
},
[ATOMIC_TYPE_FLOAT] = {
.size = 4,
.alignment = 4,
.flags = ATOMIC_TYPE_FLAG_FLOAT | ATOMIC_TYPE_FLAG_ARITHMETIC
| ATOMIC_TYPE_FLAG_SIGNED,
+ .rank = 0,
},
[ATOMIC_TYPE_DOUBLE] = {
.size = 8,
.alignment = 8,
.flags = ATOMIC_TYPE_FLAG_FLOAT | ATOMIC_TYPE_FLAG_ARITHMETIC
| ATOMIC_TYPE_FLAG_SIGNED,
+ .rank = 0,
+ },
+ [ATOMIC_TYPE_WCHAR_T] = {
+ .size = (unsigned)-1,
+ .alignment = (unsigned)-1,
+ .flags = ATOMIC_TYPE_FLAG_INTEGER | ATOMIC_TYPE_FLAG_ARITHMETIC,
+ .rank = (unsigned)-1,
},
};
atomic_type_properties_t pointer_properties = {
pointer_properties.alignment = long_size;
pointer_properties.struct_alignment = long_size;
- props[ATOMIC_TYPE_LONGLONG] = props[ATOMIC_TYPE_LONG];
- props[ATOMIC_TYPE_ULONGLONG] = props[ATOMIC_TYPE_ULONG];
props[ATOMIC_TYPE_LONG_DOUBLE] = props[ATOMIC_TYPE_DOUBLE];
props[ATOMIC_TYPE_WCHAR_T] = props[ATOMIC_TYPE_INT];
/* set struct alignments to the same value as alignment */
- for (size_t i = 0;
- i < sizeof(atomic_type_properties)/sizeof(atomic_type_properties[0]);
- ++i) {
+ for (size_t i = 0; i != lengthof(atomic_type_properties); ++i) {
props[i].struct_alignment = props[i].alignment;
}
}
{
size_t sep = q & QUAL_SEP_START ? 0 : 1;
if (qualifiers & TYPE_QUALIFIER_CONST) {
- print_string(" const" + sep);
+ print_string(&" const"[sep]);
sep = 0;
}
if (qualifiers & TYPE_QUALIFIER_VOLATILE) {
- print_string(" volatile" + sep);
+ print_string(&" volatile"[sep]);
sep = 0;
}
if (qualifiers & TYPE_QUALIFIER_RESTRICT) {
- print_string(" restrict" + sep);
+ print_string(&" restrict"[sep]);
sep = 0;
}
if (sep == 0 && q & QUAL_SEP_END)
const char *get_atomic_kind_name(atomic_type_kind_t kind)
{
- switch(kind) {
- case ATOMIC_TYPE_INVALID: break;
+ switch (kind) {
case ATOMIC_TYPE_VOID: return "void";
case ATOMIC_TYPE_WCHAR_T: return "wchar_t";
case ATOMIC_TYPE_BOOL: return c_mode & _CXX ? "bool" : "_Bool";
*
* @param type The type.
*/
-static void print_complex_type(const complex_type_t *type)
+static void print_complex_type(const atomic_type_t *type)
{
print_type_qualifiers(type->base.qualifiers, QUAL_SEP_END);
- print_string("_Complex");
+ print_string("_Complex ");
print_atomic_kinds(type->akind);
}
*
* @param type The type.
*/
-static void print_imaginary_type(const imaginary_type_t *type)
+static void print_imaginary_type(const atomic_type_t *type)
{
print_type_qualifiers(type->base.qualifiers, QUAL_SEP_END);
print_string("_Imaginary ");
static void print_function_type_post(const function_type_t *type,
const scope_t *parameters)
{
- print_string("(");
- bool first = true;
+ print_char('(');
+ separator_t sep = { "", ", " };
if (parameters == NULL) {
function_parameter_t *parameter = type->parameters;
- for( ; parameter != NULL; parameter = parameter->next) {
- if (first) {
- first = false;
- } else {
- print_string(", ");
- }
+ for ( ; parameter != NULL; parameter = parameter->next) {
+ print_string(sep_next(&sep));
print_type(parameter->type);
}
} else {
if (parameter->kind != ENTITY_PARAMETER)
continue;
- if (first) {
- first = false;
- } else {
- print_string(", ");
- }
+ print_string(sep_next(&sep));
const type_t *const param_type = parameter->declaration.type;
if (param_type == NULL) {
print_string(parameter->base.symbol->string);
}
}
if (type->variadic) {
- if (first) {
- first = false;
- } else {
- print_string(", ");
- }
+ print_string(sep_next(&sep));
print_string("...");
}
- if (first && !type->unspecified_parameters) {
+ if (sep_at_first(&sep) && !type->unspecified_parameters) {
print_string("void");
}
- print_string(")");
+ print_char(')');
intern_print_type_post(type->return_type);
}
print_string(variable->base.base.symbol->string);
print_string(") ");
}
- print_string("*");
+ print_char('*');
print_type_qualifiers(type->base.qualifiers, QUAL_SEP_START);
}
{
type_t const *const points_to = type->points_to;
if (points_to->kind == TYPE_ARRAY || points_to->kind == TYPE_FUNCTION)
- print_string(")");
+ print_char(')');
intern_print_type_post(points_to);
}
intern_print_type_pre(refers_to);
if (refers_to->kind == TYPE_ARRAY || refers_to->kind == TYPE_FUNCTION)
print_string(" (");
- print_string("&");
+ print_char('&');
}
/**
{
type_t const *const refers_to = type->refers_to;
if (refers_to->kind == TYPE_ARRAY || refers_to->kind == TYPE_FUNCTION)
- print_string(")");
+ print_char(')');
intern_print_type_post(refers_to);
}
*/
static void print_array_type_post(const array_type_t *type)
{
- print_string("[");
+ print_char('[');
if (type->is_static) {
print_string("static ");
}
&& (print_implicit_array_size || !type->has_implicit_size)) {
print_expression(type->size_expression);
}
- print_string("]");
+ print_char(']');
intern_print_type_post(type->element_type);
}
-/**
- * Prints an enum definition.
- *
- * @param declaration The enum's type declaration.
- */
void print_enum_definition(const enum_t *enume)
{
print_string("{\n");
change_indent(1);
entity_t *entry = enume->base.next;
- for( ; entry != NULL && entry->kind == ENTITY_ENUM_VALUE;
+ for ( ; entry != NULL && entry->kind == ENTITY_ENUM_VALUE;
entry = entry->base.next) {
print_indent();
print_string(entry->base.symbol->string);
if (entry->enum_value.value != NULL) {
print_string(" = ");
-
- /* skip the implicit cast */
- expression_t *expression = entry->enum_value.value;
- print_expression(expression);
+ print_expression(entry->enum_value.value);
}
print_string(",\n");
}
change_indent(-1);
print_indent();
- print_string("}");
+ print_char('}');
}
/**
*/
static void print_type_enum(const enum_type_t *type)
{
- print_type_qualifiers(type->base.qualifiers, QUAL_SEP_END);
+ print_type_qualifiers(type->base.base.qualifiers, QUAL_SEP_END);
print_string("enum ");
enum_t *enume = type->enume;
}
}
-/**
- * Print the compound part of a compound type.
- */
void print_compound_definition(const compound_t *compound)
{
print_string("{\n");
change_indent(1);
entity_t *entity = compound->members.entities;
- for( ; entity != NULL; entity = entity->base.next) {
+ for ( ; entity != NULL; entity = entity->base.next) {
if (entity->kind != ENTITY_COMPOUND_MEMBER)
continue;
print_indent();
print_entity(entity);
- print_string("\n");
+ print_char('\n');
}
change_indent(-1);
print_indent();
- print_string("}");
+ print_char('}');
if (compound->modifiers & DM_TRANSPARENT_UNION) {
print_string("__attribute__((__transparent_union__))");
}
/**
* Prints a compound type.
*
+ * @param kind The name of the compound kind.
* @param type The compound type.
*/
-static void print_compound_type(const compound_type_t *type)
+static void print_compound_type(char const *const kind, compound_type_t const *const type)
{
print_type_qualifiers(type->base.qualifiers, QUAL_SEP_END);
-
- if (type->base.kind == TYPE_COMPOUND_STRUCT) {
- print_string("struct ");
- } else {
- assert(type->base.kind == TYPE_COMPOUND_UNION);
- print_string("union ");
- }
+ print_string(kind);
compound_t *compound = type->compound;
symbol_t *symbol = compound->base.symbol;
} else {
print_type(type->typeof_type);
}
- print_string(")");
+ print_char(')');
}
/**
*/
static void intern_print_type_pre(const type_t *const type)
{
- switch(type->kind) {
- case TYPE_ERROR:
- print_string("<error>");
- return;
- case TYPE_ENUM:
- print_type_enum(&type->enumt);
- return;
- case TYPE_ATOMIC:
- print_atomic_type(&type->atomic);
- return;
- case TYPE_COMPLEX:
- print_complex_type(&type->complex);
- return;
- case TYPE_IMAGINARY:
- print_imaginary_type(&type->imaginary);
- return;
- case TYPE_COMPOUND_STRUCT:
- case TYPE_COMPOUND_UNION:
- print_compound_type(&type->compound);
- return;
- case TYPE_FUNCTION:
- print_function_type_pre(&type->function);
- return;
- case TYPE_POINTER:
- print_pointer_type_pre(&type->pointer);
- return;
- case TYPE_REFERENCE:
- print_reference_type_pre(&type->reference);
- return;
- case TYPE_ARRAY:
- print_array_type_pre(&type->array);
- return;
- case TYPE_TYPEDEF:
- print_typedef_type_pre(&type->typedeft);
- return;
- case TYPE_TYPEOF:
- print_typeof_type_pre(&type->typeoft);
- return;
+ switch (type->kind) {
+ case TYPE_ARRAY: print_array_type_pre( &type->array); return;
+ case TYPE_ATOMIC: print_atomic_type( &type->atomic); return;
+ case TYPE_COMPLEX: print_complex_type( &type->atomic); return;
+ case TYPE_COMPOUND_STRUCT: print_compound_type("struct ", &type->compound); return;
+ case TYPE_COMPOUND_UNION: print_compound_type("union ", &type->compound); return;
+ case TYPE_ENUM: print_type_enum( &type->enumt); return;
+ case TYPE_ERROR: print_string("<error>"); return;
+ case TYPE_FUNCTION: print_function_type_pre( &type->function); return;
+ case TYPE_IMAGINARY: print_imaginary_type( &type->atomic); return;
+ case TYPE_POINTER: print_pointer_type_pre( &type->pointer); return;
+ case TYPE_REFERENCE: print_reference_type_pre( &type->reference); return;
+ case TYPE_TYPEDEF: print_typedef_type_pre( &type->typedeft); return;
+ case TYPE_TYPEOF: print_typeof_type_pre( &type->typeoft); return;
}
print_string("unknown");
}
*/
static void intern_print_type_post(const type_t *const type)
{
- switch(type->kind) {
+ switch (type->kind) {
case TYPE_FUNCTION:
print_function_type_post(&type->function, NULL);
return;
}
}
-/**
- * Prints a type.
- *
- * @param type The type.
- */
void print_type(const type_t *const type)
{
print_type_ext(type, NULL, NULL);
{
intern_print_type_pre(type);
if (symbol != NULL) {
- print_string(" ");
+ print_char(' ');
print_string(symbol->string);
}
if (type->kind == TYPE_FUNCTION) {
}
}
-/**
- * Duplicates a type.
- *
- * @param type The type to copy.
- * @return A copy of the type.
- *
- * @note This does not produce a deep copy!
- */
type_t *duplicate_type(const type_t *type)
{
size_t size = get_type_struct_size(type->kind);
- type_t *const copy = obstack_alloc(&type_obst, size);
- memcpy(copy, type, size);
+ type_t *const copy = obstack_copy(&type_obst, type, size);
copy->base.firm_type = NULL;
return copy;
}
-/**
- * Returns the unqualified type of a given type.
- *
- * @param type The type.
- * @returns The unqualified type.
- */
type_t *get_unqualified_type(type_t *type)
{
assert(!is_typeref(type));
return (atomic_type_properties[kind].flags & flag) != 0;
}
-/**
- * Returns true if the given type is an integer type.
- *
- * @param type The type to check.
- * @return True if type is an integer type.
- */
bool is_type_integer(const type_t *type)
{
assert(!is_typeref(type));
-
- if (type->kind == TYPE_ENUM)
- return true;
- if (type->kind != TYPE_ATOMIC)
+ if (!is_type_arithmetic(type))
return false;
-
return test_atomic_type_flag(type->atomic.akind, ATOMIC_TYPE_FLAG_INTEGER);
}
-/**
- * Returns true if the given type is an enum type.
- *
- * @param type The type to check.
- * @return True if type is an enum type.
- */
bool is_type_enum(const type_t *type)
{
assert(!is_typeref(type));
return type->kind == TYPE_ENUM;
}
-/**
- * Returns true if the given type is an floating point type.
- *
- * @param type The type to check.
- * @return True if type is a floating point type.
- */
bool is_type_float(const type_t *type)
{
assert(!is_typeref(type));
return test_atomic_type_flag(type->atomic.akind, ATOMIC_TYPE_FLAG_FLOAT);
}
-/**
- * Returns true if the given type is an complex type.
- *
- * @param type The type to check.
- * @return True if type is a complex type.
- */
bool is_type_complex(const type_t *type)
{
assert(!is_typeref(type));
-
- if (type->kind != TYPE_ATOMIC)
- return false;
-
- return test_atomic_type_flag(type->atomic.akind, ATOMIC_TYPE_FLAG_COMPLEX);
+ return type->kind == TYPE_COMPLEX;
}
-/**
- * Returns true if the given type is a signed type.
- *
- * @param type The type to check.
- * @return True if type is a signed type.
- */
bool is_type_signed(const type_t *type)
{
assert(!is_typeref(type));
-
- /* enum types are int for now */
- if (type->kind == TYPE_ENUM)
- return true;
- if (type->kind != TYPE_ATOMIC)
+ if (!is_type_arithmetic(type))
return false;
-
return test_atomic_type_flag(type->atomic.akind, ATOMIC_TYPE_FLAG_SIGNED);
}
-/**
- * Returns true if the given type represents an arithmetic type.
- *
- * @param type The type to check.
- * @return True if type represents an arithmetic type.
- */
bool is_type_arithmetic(const type_t *type)
{
assert(!is_typeref(type));
- switch(type->kind) {
+ switch (type->kind) {
case TYPE_ENUM:
return true;
case TYPE_ATOMIC:
- return test_atomic_type_flag(type->atomic.akind, ATOMIC_TYPE_FLAG_ARITHMETIC);
case TYPE_COMPLEX:
- return test_atomic_type_flag(type->complex.akind, ATOMIC_TYPE_FLAG_ARITHMETIC);
case TYPE_IMAGINARY:
- return test_atomic_type_flag(type->imaginary.akind, ATOMIC_TYPE_FLAG_ARITHMETIC);
+ return test_atomic_type_flag(type->atomic.akind, ATOMIC_TYPE_FLAG_ARITHMETIC);
default:
return false;
}
}
-/**
- * Returns true if the given type is an integer or float type.
- *
- * @param type The type to check.
- * @return True if type is an integer or float type.
- */
bool is_type_real(const type_t *type)
{
/* 6.2.5 (17) */
return is_type_integer(type) || is_type_float(type);
}
-/**
- * Returns true if the given type represents a scalar type.
- *
- * @param type The type to check.
- * @return True if type represents a scalar type.
- */
bool is_type_scalar(const type_t *type)
{
assert(!is_typeref(type));
- if (type->kind == TYPE_POINTER)
+ switch (type->kind) {
+ case TYPE_POINTER:
+ case TYPE_ENUM:
return true;
-
- return is_type_arithmetic(type);
+ case TYPE_ATOMIC:
+ case TYPE_COMPLEX:
+ case TYPE_IMAGINARY:
+ return test_atomic_type_flag(type->atomic.akind, ATOMIC_TYPE_FLAG_ARITHMETIC);
+ default:
+ return false;
+ }
}
-/**
- * Check if a given type is incomplete.
- *
- * @param type The type to check.
- * @return True if the given type is incomplete (ie. just forward).
- */
bool is_type_incomplete(const type_t *type)
{
assert(!is_typeref(type));
- switch(type->kind) {
+ switch (type->kind) {
case TYPE_COMPOUND_STRUCT:
case TYPE_COMPOUND_UNION: {
const compound_type_t *compound_type = &type->compound;
&& !type->array.size_constant;
case TYPE_ATOMIC:
- return type->atomic.akind == ATOMIC_TYPE_VOID;
-
- case TYPE_COMPLEX:
- return type->complex.akind == ATOMIC_TYPE_VOID;
-
case TYPE_IMAGINARY:
- return type->imaginary.akind == ATOMIC_TYPE_VOID;
+ case TYPE_COMPLEX:
+ return type->atomic.akind == ATOMIC_TYPE_VOID;
case TYPE_FUNCTION:
case TYPE_POINTER:
case TYPE_TYPEDEF:
case TYPE_TYPEOF:
- panic("is_type_incomplete called without typerefs skipped");
+ panic("typedef not skipped");
}
- panic("invalid type found");
+ panic("invalid type");
}
bool is_type_object(const type_t *type)
return array1->size == array2->size;
}
-/**
- * Check if two types are compatible.
- */
bool types_compatible(const type_t *type1, const type_t *type2)
{
assert(!is_typeref(type1));
if (type1 == type2)
return true;
- if (!is_type_valid(type1) || !is_type_valid(type2))
- return true;
-
- if (type1->base.qualifiers != type2->base.qualifiers)
- return false;
- if (type1->kind != type2->kind)
- return false;
+ if (type1->base.qualifiers == type2->base.qualifiers &&
+ type1->kind == type2->kind) {
+ switch (type1->kind) {
+ case TYPE_FUNCTION:
+ return function_types_compatible(&type1->function, &type2->function);
+ case TYPE_ATOMIC:
+ case TYPE_IMAGINARY:
+ case TYPE_COMPLEX:
+ return type1->atomic.akind == type2->atomic.akind;
+ case TYPE_ARRAY:
+ return array_types_compatible(&type1->array, &type2->array);
- switch (type1->kind) {
- case TYPE_FUNCTION:
- return function_types_compatible(&type1->function, &type2->function);
- case TYPE_ATOMIC:
- return type1->atomic.akind == type2->atomic.akind;
- case TYPE_COMPLEX:
- return type1->complex.akind == type2->complex.akind;
- case TYPE_IMAGINARY:
- return type1->imaginary.akind == type2->imaginary.akind;
- case TYPE_ARRAY:
- return array_types_compatible(&type1->array, &type2->array);
+ case TYPE_POINTER: {
+ const type_t *const to1 = skip_typeref(type1->pointer.points_to);
+ const type_t *const to2 = skip_typeref(type2->pointer.points_to);
+ return types_compatible(to1, to2);
+ }
- case TYPE_POINTER: {
- const type_t *const to1 = skip_typeref(type1->pointer.points_to);
- const type_t *const to2 = skip_typeref(type2->pointer.points_to);
- return types_compatible(to1, to2);
- }
+ case TYPE_REFERENCE: {
+ const type_t *const to1 = skip_typeref(type1->reference.refers_to);
+ const type_t *const to2 = skip_typeref(type2->reference.refers_to);
+ return types_compatible(to1, to2);
+ }
- case TYPE_REFERENCE: {
- const type_t *const to1 = skip_typeref(type1->reference.refers_to);
- const type_t *const to2 = skip_typeref(type2->reference.refers_to);
- return types_compatible(to1, to2);
- }
+ case TYPE_COMPOUND_STRUCT:
+ case TYPE_COMPOUND_UNION:
+ break;
- case TYPE_COMPOUND_STRUCT:
- case TYPE_COMPOUND_UNION: {
- break;
- }
- case TYPE_ENUM:
- /* TODO: not implemented */
- break;
+ case TYPE_ENUM:
+ /* TODO: not implemented */
+ break;
- case TYPE_ERROR:
- /* Hmm, the error type should be compatible to all other types */
- return true;
- case TYPE_TYPEDEF:
- case TYPE_TYPEOF:
- panic("typerefs not skipped in compatible types?!?");
+ case TYPE_ERROR:
+ /* Hmm, the error type should be compatible to all other types */
+ return true;
+ case TYPE_TYPEDEF:
+ case TYPE_TYPEOF:
+ panic("typeref not skipped");
+ }
}
- return false;
+ return !is_type_valid(type1) || !is_type_valid(type2);
}
/**
case TYPE_ERROR:
return 0;
case TYPE_ATOMIC:
+ case TYPE_IMAGINARY:
+ case TYPE_ENUM:
return get_atomic_type_size(type->atomic.akind);
case TYPE_COMPLEX:
- return get_atomic_type_size(type->complex.akind) * 2;
- case TYPE_IMAGINARY:
- return get_atomic_type_size(type->imaginary.akind);
+ return get_atomic_type_size(type->atomic.akind) * 2;
case TYPE_COMPOUND_UNION:
layout_union_type(&type->compound);
return type->compound.compound->size;
case TYPE_COMPOUND_STRUCT:
layout_struct_type(&type->compound);
return type->compound.compound->size;
- case TYPE_ENUM:
- return get_atomic_type_size(type->enumt.akind);
case TYPE_FUNCTION:
- return 0; /* non-const (but "address-const") */
+ return 1; /* strange GNU extensions: sizeof(function) == 1 */
case TYPE_REFERENCE:
case TYPE_POINTER:
return pointer_properties.size;
case TYPE_TYPEDEF:
return get_type_size(type->typedeft.typedefe->type);
case TYPE_TYPEOF:
- if (type->typeoft.typeof_type) {
- return get_type_size(type->typeoft.typeof_type);
- } else {
- return get_type_size(type->typeoft.expression->base.type);
- }
+ return get_type_size(type->typeoft.typeof_type);
}
- panic("invalid type in get_type_size");
+ panic("invalid type");
}
unsigned get_type_alignment(type_t *type)
case TYPE_ERROR:
return 0;
case TYPE_ATOMIC:
- return get_atomic_type_alignment(type->atomic.akind);
- case TYPE_COMPLEX:
- return get_atomic_type_alignment(type->complex.akind);
case TYPE_IMAGINARY:
- return get_atomic_type_alignment(type->imaginary.akind);
+ case TYPE_COMPLEX:
+ case TYPE_ENUM:
+ return get_atomic_type_alignment(type->atomic.akind);
case TYPE_COMPOUND_UNION:
layout_union_type(&type->compound);
return type->compound.compound->alignment;
case TYPE_COMPOUND_STRUCT:
layout_struct_type(&type->compound);
return type->compound.compound->alignment;
- case TYPE_ENUM:
- return get_atomic_type_alignment(type->enumt.akind);
case TYPE_FUNCTION:
/* gcc says 1 here... */
return 1;
return alignment;
}
case TYPE_TYPEOF:
- if (type->typeoft.typeof_type) {
- return get_type_alignment(type->typeoft.typeof_type);
- } else {
- return get_type_alignment(type->typeoft.expression->base.type);
- }
+ return get_type_alignment(type->typeoft.typeof_type);
}
- panic("invalid type in get_type_alignment");
+ panic("invalid type");
}
-unsigned get_type_alignment_compound(type_t *type)
+/**
+ * get alignment of a type when used inside a compound.
+ * Some ABIs are broken and alignment inside a compound is different from
+ * recommended alignment of a type
+ */
+static unsigned get_type_alignment_compound(type_t *const type)
{
+ assert(!is_typeref(type));
if (type->kind == TYPE_ATOMIC)
return atomic_type_properties[type->atomic.akind].struct_alignment;
return get_type_alignment(type);
decl_modifiers_t get_type_modifiers(const type_t *type)
{
- switch(type->kind) {
+ switch (type->kind) {
case TYPE_ERROR:
break;
case TYPE_COMPOUND_STRUCT:
return modifiers;
}
case TYPE_TYPEOF:
- if (type->typeoft.typeof_type) {
- return get_type_modifiers(type->typeoft.typeof_type);
- } else {
- return get_type_modifiers(type->typeoft.expression->base.type);
- }
+ return get_type_modifiers(type->typeoft.typeof_type);
}
- panic("invalid type found in get_type_modifiers");
+ panic("invalid type");
}
type_qualifiers_t get_type_qualifier(const type_t *type, bool skip_array_type)
assert(size < 32);
atomic_type_kind_t kind = kinds[size];
- if (kind == ATOMIC_TYPE_INVALID) {
+ if (kind == (atomic_type_kind_t)0) {
static const atomic_type_kind_t possible_kinds[] = {
ATOMIC_TYPE_SCHAR,
ATOMIC_TYPE_SHORT,
assert(size < 32);
atomic_type_kind_t kind = kinds[size];
- if (kind == ATOMIC_TYPE_INVALID) {
+ if (kind == (atomic_type_kind_t)0) {
static const atomic_type_kind_t possible_kinds[] = {
ATOMIC_TYPE_UCHAR,
ATOMIC_TYPE_USHORT,
* @param akind The kind of the atomic type.
* @param qualifiers Type qualifiers for the new type.
*/
-type_t *make_complex_type(atomic_type_kind_t akind, type_qualifiers_t qualifiers)
+type_t *make_complex_type(atomic_type_kind_t akind,
+ type_qualifiers_t qualifiers)
{
type_t *const type = allocate_type_zero(TYPE_COMPLEX);
type->base.qualifiers = qualifiers;
- type->complex.akind = akind;
+ type->atomic.akind = akind;
return identify_new_type(type);
}
* @param akind The kind of the atomic type.
* @param qualifiers Type qualifiers for the new type.
*/
-type_t *make_imaginary_type(atomic_type_kind_t akind, type_qualifiers_t qualifiers)
+type_t *make_imaginary_type(atomic_type_kind_t akind,
+ type_qualifiers_t qualifiers)
{
type_t *const type = allocate_type_zero(TYPE_IMAGINARY);
type->base.qualifiers = qualifiers;
- type->imaginary.akind = akind;
+ type->atomic.akind = akind;
return identify_new_type(type);
}
if (!member->compound_member.bitfield)
break;
- type_t *base_type = member->declaration.type;
+ type_t *const base_type = skip_typeref(member->declaration.type);
il_alignment_t base_alignment = get_type_alignment_compound(base_type);
il_alignment_t alignment_mask = base_alignment-1;
if (base_alignment > alignment)
return;
if (type->compound->layouted)
return;
+ compound->layouted = true;
il_size_t offset = 0;
il_alignment_t alignment = compound->alignment;
entity_t *entry = compound->members.entities;
while (entry != NULL) {
- if (entry->kind != ENTITY_COMPOUND_MEMBER) {
- entry = entry->base.next;
- continue;
- }
+ if (entry->kind != ENTITY_COMPOUND_MEMBER)
+ goto next;
- type_t *m_type = entry->declaration.type;
- type_t *skipped = skip_typeref(m_type);
- if (! is_type_valid(skipped)) {
- entry = entry->base.next;
- continue;
- }
+ type_t *const m_type = skip_typeref(entry->declaration.type);
+ if (!is_type_valid(m_type))
+ goto next;
if (entry->compound_member.bitfield) {
entry = pack_bitfield_members(&offset, &alignment,
entry->compound_member.offset = offset;
offset += get_type_size(m_type);
+next:
entry = entry->base.next;
}
}
}
- source_position_t const *const pos = &compound->base.source_position;
+ position_t const *const pos = &compound->base.pos;
if (need_pad) {
warningf(WARN_PADDED, pos, "'%T' needs padding", type);
} else if (compound->packed) {
compound->size = offset;
compound->alignment = alignment;
- compound->layouted = true;
}
void layout_union_type(compound_type_t *type)
compound_t *compound = type->compound;
if (! compound->complete)
return;
+ if (compound->layouted)
+ return;
+ compound->layouted = true;
il_size_t size = 0;
il_alignment_t alignment = compound->alignment;
if (entry->kind != ENTITY_COMPOUND_MEMBER)
continue;
- type_t *m_type = entry->declaration.type;
+ type_t *m_type = skip_typeref(entry->declaration.type);
if (! is_type_valid(skip_typeref(m_type)))
continue;
}
type_t *make_function_2_type(type_t *return_type, type_t *argument_type1,
- type_t *argument_type2)
+ type_t *argument_type2, decl_modifiers_t modifiers)
{
function_parameter_t *const parameter2 = allocate_parameter(argument_type2);
function_parameter_t *const parameter1 = allocate_parameter(argument_type1);
type_t *type = allocate_type_zero(TYPE_FUNCTION);
type->function.return_type = return_type;
type->function.parameters = parameter1;
+ type->function.modifiers |= modifiers;
type->function.linkage = LINKAGE_C;
return identify_new_type(type);
}
-type_t *make_function_1_type(type_t *return_type, type_t *argument_type)
+type_t *make_function_1_type(type_t *return_type, type_t *argument_type,
+ decl_modifiers_t modifiers)
{
function_parameter_t *const parameter = allocate_parameter(argument_type);
type_t *type = allocate_type_zero(TYPE_FUNCTION);
type->function.return_type = return_type;
type->function.parameters = parameter;
+ type->function.modifiers |= modifiers;
type->function.linkage = LINKAGE_C;
return identify_new_type(type);
}
type_t *make_function_1_type_variadic(type_t *return_type,
- type_t *argument_type)
+ type_t *argument_type,
+ decl_modifiers_t modifiers)
{
function_parameter_t *const parameter = allocate_parameter(argument_type);
type->function.return_type = return_type;
type->function.parameters = parameter;
type->function.variadic = true;
+ type->function.modifiers |= modifiers;
type->function.linkage = LINKAGE_C;
return identify_new_type(type);
}
-type_t *make_function_0_type(type_t *return_type)
+type_t *make_function_0_type(type_t *return_type, decl_modifiers_t modifiers)
{
type_t *type = allocate_type_zero(TYPE_FUNCTION);
type->function.return_type = return_type;
type->function.parameters = NULL;
+ type->function.modifiers |= modifiers;
type->function.linkage = LINKAGE_C;
return identify_new_type(type);
{
print_to_file(stderr);
print_type(type);
- print_string("\n");
+ print_char('\n');
fflush(stderr);
}