static declaration_t *current_function = NULL;
static switch_statement_t *current_switch = NULL;
static statement_t *current_loop = NULL;
+static ms_try_statement_t *current_try = NULL;
static goto_statement_t *goto_first = NULL;
static goto_statement_t *goto_last = NULL;
static label_statement_t *label_first = NULL;
static unsigned char token_anchor_set[T_LAST_TOKEN];
/** The current source position. */
-#define HERE &token.source_position
+#define HERE (&token.source_position)
static type_t *type_valist;
-static statement_t *parse_compound_statement(void);
+static statement_t *parse_compound_statement(bool inside_expression_statement);
static statement_t *parse_statement(void);
static expression_t *parse_sub_expression(unsigned precedence);
[STATEMENT_WHILE] = sizeof(while_statement_t),
[STATEMENT_DO_WHILE] = sizeof(do_while_statement_t),
[STATEMENT_FOR] = sizeof(for_statement_t),
- [STATEMENT_ASM] = sizeof(asm_statement_t)
+ [STATEMENT_ASM] = sizeof(asm_statement_t),
+ [STATEMENT_MS_TRY] = sizeof(ms_try_statement_t),
+ [STATEMENT_LEAVE] = sizeof(leave_statement_t)
};
assert(kind <= sizeof(sizes) / sizeof(sizes[0]));
assert(sizes[kind] != 0);
{
static const size_t sizes[] = {
[TYPE_ATOMIC] = sizeof(atomic_type_t),
+ [TYPE_COMPLEX] = sizeof(complex_type_t),
+ [TYPE_IMAGINARY] = sizeof(imaginary_type_t),
[TYPE_BITFIELD] = sizeof(bitfield_type_t),
[TYPE_COMPOUND_STRUCT] = sizeof(compound_type_t),
[TYPE_COMPOUND_UNION] = sizeof(compound_type_t),
++token_anchor_set[token_type];
}
+static int save_and_reset_anchor_state(int token_type) {
+ assert(0 <= token_type && token_type < T_LAST_TOKEN);
+ int count = token_anchor_set[token_type];
+ token_anchor_set[token_type] = 0;
+ return count;
+}
+
+static void restore_anchor_state(int token_type, int count) {
+ assert(0 <= token_type && token_type < T_LAST_TOKEN);
+ token_anchor_set[token_type] = count;
+}
+
/**
* Remove a token from the token anchor set (a multi-set).
*/
}
/**
- * eat all token until a ';' is reached
- * or a stop token is found.
+ * eat all token until a ';' is reached or a stop token is found.
*/
static void eat_statement(void) {
eat_until_matching_token(';');
/**
* Report a parse error because an expected token was not found.
*/
-static void parse_error_expected(const char *message, ...)
+static
+#if defined __GNUC__ && __GNUC__ >= 4
+__attribute__((sentinel))
+#endif
+void parse_error_expected(const char *message, ...)
{
if(message != NULL) {
errorf(HERE, "%s", message);
}
va_list ap;
va_start(ap, message);
- errorf(HERE, "got %K, expected %#k", &token, &ap, "a ");
+ errorf(HERE, "got %K, expected %#k", &token, &ap, ", ");
va_end(ap);
}
static void type_error_incompatible(const char *msg,
const source_position_t *source_position, type_t *type1, type_t *type2)
{
- errorf(source_position, "%s, incompatible types: '%T' - '%T'", msg, type1, type2);
+ errorf(source_position, "%s, incompatible types: '%T' - '%T'",
+ msg, type1, type2);
}
/**
* If not, generate an error, eat the current statement,
* and goto the end_error label.
*/
-#define expect(expected) \
- do { \
- if(UNLIKELY(token.type != (expected))) { \
- parse_error_expected(NULL, (expected), 0); \
- add_anchor_token(expected); \
- eat_until_anchor(); \
- rem_anchor_token(expected); \
- goto end_error; \
- } \
- next_token(); \
+#define expect(expected) \
+ do { \
+ if(UNLIKELY(token.type != (expected))) { \
+ parse_error_expected(NULL, (expected), NULL); \
+ add_anchor_token(expected); \
+ eat_until_anchor(); \
+ if (token.type == expected) \
+ next_token(); \
+ rem_anchor_token(expected); \
+ goto end_error; \
+ } \
+ next_token(); \
} while(0)
static void set_scope(scope_t *new_scope)
static int get_rank(const type_t *type)
{
assert(!is_typeref(type));
- /* The C-standard allows promoting to int or unsigned int (see § 7.2.2
+ /* The C-standard allows promoting enums to int or unsigned int (see § 7.2.2
* and esp. footnote 108). However we can't fold constants (yet), so we
* can't decide whether unsigned int is possible, while int always works.
* (unsigned int would be preferable when possible... for stuff like
static type_t *promote_integer(type_t *type)
{
if(type->kind == TYPE_BITFIELD)
- type = type->bitfield.base;
+ type = type->bitfield.base_type;
if(get_rank(type) < ATOMIC_TYPE_INT)
type = type_int;
expression_t *result = parse_sub_expression(7);
if(!is_constant_expression(result)) {
- errorf(&result->base.source_position, "expression '%E' is not constant\n", result);
+ errorf(&result->base.source_position,
+ "expression '%E' is not constant\n", result);
}
return result;
[GNU_AK_TLS_MODEL] = "tls_model",
[GNU_AK_VISIBILITY] = "visibility",
[GNU_AK_REGPARM] = "regparm",
+ [GNU_AK_MODE] = "mode",
[GNU_AK_MODEL] = "model",
[GNU_AK_TRAP_EXIT] = "trap_exit",
[GNU_AK_SP_SWITCH] = "sp_switch",
*/
static gnu_attribute_t *allocate_gnu_attribute(gnu_attribute_kind_t kind) {
gnu_attribute_t *attribute = obstack_alloc(&temp_obst, sizeof(*attribute));
- attribute->kind = kind;
- attribute->next = NULL;
- attribute->invalid = false;
- attribute->have_arguments = false;
+ attribute->kind = kind;
+ attribute->next = NULL;
+ attribute->invalid = false;
+ attribute->have_arguments = false;
+
+ return attribute;
return attribute;
}
/**
* parse one string literal argument.
*/
-static void parse_gnu_attribute_string_arg(gnu_attribute_t *attribute, string_t *string) {
+static void parse_gnu_attribute_string_arg(gnu_attribute_t *attribute,
+ string_t *string)
+{
add_anchor_token('(');
if(token.type != T_STRING_LITERAL) {
- parse_error_expected("while parsing attribute directive", T_STRING_LITERAL);
+ parse_error_expected("while parsing attribute directive",
+ T_STRING_LITERAL, NULL);
goto end_error;
}
*string = parse_string_literals();
attribute->invalid = true;
}
+static void parse_gnu_attribute_mode_arg(gnu_attribute_t *attribute)
+{
+ /* TODO: find out what is allowed here... */
+
+ /* at least: byte, word, pointer, list of machine modes
+ * __XXX___ is interpreted as XXX */
+ add_anchor_token(')');
+ expect(T_IDENTIFIER);
+ rem_anchor_token(')');
+ expect(')');
+ return;
+end_error:
+ attribute->invalid = true;
+}
+
/**
* parse one interrupt argument.
*/
int i;
if(token.type != T_IDENTIFIER) {
- parse_error_expected("while parsing format attribute directive", T_IDENTIFIER);
+ parse_error_expected("while parsing format attribute directive", T_IDENTIFIER, NULL);
goto end_error;
}
const char *name = token.v.symbol->string;
/* __attribute__((cdecl)), WITH ms mode */
name = "cdecl";
} else if(token.type != T_IDENTIFIER) {
- parse_error_expected("while parsing GNU attribute", T_IDENTIFIER);
+ parse_error_expected("while parsing GNU attribute", T_IDENTIFIER, NULL);
break;
}
const symbol_t *sym = token.v.symbol;
if(!attribute->have_arguments) {
/* should have arguments */
errorf(HERE, "wrong number of arguments specified for '%s' attribute", name);
- } else
+ } else {
parse_gnu_attribute_model_arg(attribute);
+ }
+ break;
+ case GNU_AK_MODE:
+ if(!attribute->have_arguments) {
+ /* should have arguments */
+ errorf(HERE, "wrong number of arguments specified for '%s' attribute", name);
+ } else {
+ parse_gnu_attribute_mode_arg(attribute);
+ }
+ break;
case GNU_AK_INTERRUPT:
/* may have one string argument */
if(attribute->have_arguments)
expect('(');
if(token.type != T_STRING_LITERAL) {
parse_error_expected("while parsing assembler attribute",
- T_STRING_LITERAL);
+ T_STRING_LITERAL, NULL);
eat_until_matching_token('(');
break;
} else {
next_token();
if(token.type != T_IDENTIFIER) {
parse_error_expected("while parsing designator",
- T_IDENTIFIER, 0);
+ T_IDENTIFIER, NULL);
return NULL;
}
designator->symbol = token.v.symbol;
}
/**
- * skip any {...} blocks until a closing braket is reached.
+ * skip any {...} blocks until a closing bracket is reached.
*/
static void skip_initializers(void)
{
len * sizeof(initializers[0]));
DEL_ARR_F(initializers);
- ascend_to(path, top_path_level);
+ ascend_to(path, top_path_level+1);
return result;
end_error:
skip_initializers();
DEL_ARR_F(initializers);
- ascend_to(path, top_path_level);
+ ascend_to(path, top_path_level+1);
return NULL;
}
} else if(token.type != '{') {
if(is_struct) {
parse_error_expected("while parsing struct type specifier",
- T_IDENTIFIER, '{', 0);
+ T_IDENTIFIER, '{', NULL);
} else {
parse_error_expected("while parsing union type specifier",
- T_IDENTIFIER, '{', 0);
+ T_IDENTIFIER, '{', NULL);
}
return NULL;
(is_struct ? NAMESPACE_STRUCT : NAMESPACE_UNION);
declaration->source_position = token.source_position;
declaration->symbol = symbol;
- declaration->parent_scope = scope;
+ declaration->parent_scope = scope;
if (symbol != NULL) {
environment_push(declaration);
}
}
if(token.type == '{') {
- if(declaration->init.is_defined) {
+ if (declaration->init.complete) {
assert(symbol != NULL);
errorf(HERE, "multiple definitions of '%s %Y'",
is_struct ? "struct" : "union", symbol);
declaration->scope.declarations = NULL;
}
- declaration->init.is_defined = true;
+ declaration->init.complete = true;
parse_compound_type_entries(declaration);
parse_attributes(&attributes);
add_anchor_token('}');
do {
if(token.type != T_IDENTIFIER) {
- parse_error_expected("while parsing enum entry", T_IDENTIFIER, 0);
+ parse_error_expected("while parsing enum entry", T_IDENTIFIER, NULL);
eat_block();
rem_anchor_token('}');
return;
declaration = get_declaration(symbol, NAMESPACE_ENUM);
} else if(token.type != '{') {
parse_error_expected("while parsing enum type specifier",
- T_IDENTIFIER, '{', 0);
+ T_IDENTIFIER, '{', NULL);
return NULL;
} else {
declaration = NULL;
type->enumt.declaration = declaration;
if(token.type == '{') {
- if(declaration->init.is_defined) {
+ if(declaration->init.complete) {
errorf(HERE, "multiple definitions of enum %Y", symbol);
}
if (symbol != NULL) {
environment_push(declaration);
}
append_declaration(declaration);
- declaration->init.is_defined = 1;
+ declaration->init.complete = true;
parse_enum_entries(type);
parse_attributes(&attributes);
SPECIFIER_INT32 = 1 << 13,
SPECIFIER_INT64 = 1 << 14,
SPECIFIER_INT128 = 1 << 15,
-#ifdef PROVIDE_COMPLEX
SPECIFIER_COMPLEX = 1 << 16,
SPECIFIER_IMAGINARY = 1 << 17,
-#endif
} specifiers_t;
static type_t *create_builtin_type(symbol_t *const symbol,
type->builtin.real_type = real_type;
type_t *result = typehash_insert(type);
- if (type != result) {
+ if(type != result) {
free_type(type);
}
static type_t *get_typedef_type(symbol_t *symbol)
{
declaration_t *declaration = get_declaration(symbol, NAMESPACE_NORMAL);
- if(declaration == NULL
- || declaration->storage_class != STORAGE_CLASS_TYPEDEF)
+ if(declaration == NULL ||
+ declaration->storage_class != STORAGE_CLASS_TYPEDEF)
return NULL;
type_t *type = allocate_type_zero(TYPE_TYPEDEF, &declaration->source_position);
}
}
next_token();
- if(token.type == ',') {
+ if(token.type == ',') {
next_token();
continue;
}
MATCH_SPECIFIER(T__int32, SPECIFIER_INT32, "_int32")
MATCH_SPECIFIER(T__int64, SPECIFIER_INT64, "_int64")
MATCH_SPECIFIER(T__int128, SPECIFIER_INT128, "_int128")
-#ifdef PROVIDE_COMPLEX
MATCH_SPECIFIER(T__Complex, SPECIFIER_COMPLEX, "_Complex")
MATCH_SPECIFIER(T__Imaginary, SPECIFIER_IMAGINARY, "_Imaginary")
-#endif
+
case T__forceinline:
/* only in microsoft mode */
specifiers->decl_modifiers |= DM_FORCEINLINE;
case SPECIFIER_BOOL:
atomic_type = ATOMIC_TYPE_BOOL;
break;
-#ifdef PROVIDE_COMPLEX
case SPECIFIER_FLOAT | SPECIFIER_COMPLEX:
- atomic_type = ATOMIC_TYPE_FLOAT_COMPLEX;
- break;
- case SPECIFIER_DOUBLE | SPECIFIER_COMPLEX:
- atomic_type = ATOMIC_TYPE_DOUBLE_COMPLEX;
- break;
- case SPECIFIER_LONG | SPECIFIER_DOUBLE | SPECIFIER_COMPLEX:
- atomic_type = ATOMIC_TYPE_LONG_DOUBLE_COMPLEX;
- break;
case SPECIFIER_FLOAT | SPECIFIER_IMAGINARY:
- atomic_type = ATOMIC_TYPE_FLOAT_IMAGINARY;
+ atomic_type = ATOMIC_TYPE_FLOAT;
break;
+ case SPECIFIER_DOUBLE | SPECIFIER_COMPLEX:
case SPECIFIER_DOUBLE | SPECIFIER_IMAGINARY:
- atomic_type = ATOMIC_TYPE_DOUBLE_IMAGINARY;
+ atomic_type = ATOMIC_TYPE_DOUBLE;
break;
+ case SPECIFIER_LONG | SPECIFIER_DOUBLE | SPECIFIER_COMPLEX:
case SPECIFIER_LONG | SPECIFIER_DOUBLE | SPECIFIER_IMAGINARY:
- atomic_type = ATOMIC_TYPE_LONG_DOUBLE_IMAGINARY;
+ atomic_type = ATOMIC_TYPE_LONG_DOUBLE;
break;
-#endif
default:
/* invalid specifier combination, give an error message */
if(type_specifiers == 0) {
atomic_type = ATOMIC_TYPE_INVALID;
}
- type = allocate_type_zero(TYPE_ATOMIC, &builtin_source_position);
- type->atomic.akind = atomic_type;
- newtype = 1;
+ if(type_specifiers & SPECIFIER_COMPLEX &&
+ atomic_type != ATOMIC_TYPE_INVALID) {
+ type = allocate_type_zero(TYPE_COMPLEX, &builtin_source_position);
+ type->complex.akind = atomic_type;
+ } else if(type_specifiers & SPECIFIER_IMAGINARY &&
+ atomic_type != ATOMIC_TYPE_INVALID) {
+ type = allocate_type_zero(TYPE_IMAGINARY, &builtin_source_position);
+ type->imaginary.akind = atomic_type;
+ } else {
+ type = allocate_type_zero(TYPE_ATOMIC, &builtin_source_position);
+ type->atomic.akind = atomic_type;
+ }
+ newtype = 1;
} else {
if(type_specifiers != 0) {
errorf(HERE, "multiple datatypes in declaration");
}
last_declaration = declaration;
- if(token.type != ',')
+ if (token.type != ',') {
break;
+ }
next_token();
} while(token.type == T_IDENTIFIER);
static declaration_t *parse_parameters(function_type_t *type)
{
+ declaration_t *declarations = NULL;
+
+ eat('(');
+ add_anchor_token(')');
+ int saved_comma_state = save_and_reset_anchor_state(',');
+
if(token.type == T_IDENTIFIER) {
symbol_t *symbol = token.v.symbol;
if(!is_typedef_symbol(symbol)) {
type->kr_style_parameters = true;
- return parse_identifier_list();
+ declarations = parse_identifier_list();
+ goto parameters_finished;
}
}
if(token.type == ')') {
type->unspecified_parameters = 1;
- return NULL;
+ goto parameters_finished;
}
if(token.type == T_void && look_ahead(1)->type == ')') {
next_token();
- return NULL;
+ goto parameters_finished;
}
- declaration_t *declarations = NULL;
declaration_t *declaration;
declaration_t *last_declaration = NULL;
function_parameter_t *parameter;
case T_DOTDOTDOT:
next_token();
type->variadic = 1;
- return declarations;
+ goto parameters_finished;
case T_IDENTIFIER:
case T___extension__:
break;
default:
- return declarations;
+ goto parameters_finished;
+ }
+ if (token.type != ',') {
+ goto parameters_finished;
}
- if(token.type != ',')
- return declarations;
next_token();
}
+
+
+parameters_finished:
+ rem_anchor_token(')');
+ expect(')');
+
+ restore_anchor_state(',', saved_comma_state);
+ return declarations;
+
+end_error:
+ restore_anchor_state(',', saved_comma_state);
+ return NULL;
}
typedef enum {
static construct_type_t *parse_function_declarator(declaration_t *declaration)
{
- eat('(');
- add_anchor_token(')');
-
type_t *type;
if(declaration != NULL) {
type = allocate_type_zero(TYPE_FUNCTION, &declaration->source_position);
construct_function_type->construct_type.kind = CONSTRUCT_FUNCTION;
construct_function_type->function_type = type;
- rem_anchor_token(')');
- expect(')');
-
-end_error:
return (construct_type_t*) construct_function_type;
}
default:
if(may_be_abstract)
break;
- parse_error_expected("while parsing declarator", T_IDENTIFIER, '(', 0);
+ parse_error_expected("while parsing declarator", T_IDENTIFIER, '(', NULL);
/* avoid a loop in the outermost scope, because eat_statement doesn't
* eat '}' */
if(token.type == '}' && current_function == NULL) {
{
declaration_t *const declaration = allocate_declaration_zero();
declaration->declared_storage_class = specifiers->declared_storage_class;
- declaration->modifiers = specifiers->decl_modifiers;
+ declaration->decl_modifiers = specifiers->decl_modifiers;
declaration->deprecated = specifiers->deprecated;
declaration->deprecated_string = specifiers->deprecated_string;
declaration->get_property_sym = specifiers->get_property_sym;
}
}
}
+
+ if (declaration->is_inline)
+ previous_declaration->is_inline = true;
return previous_declaration;
}
} else if (is_function_definition) {
}
static bool is_declaration_specifier(const token_t *token,
- bool only_type_specifiers)
+ bool only_specifiers_qualifiers)
{
switch(token->type) {
TYPE_SPECIFIERS
+ TYPE_QUALIFIERS
return true;
case T_IDENTIFIER:
return is_typedef_symbol(token->v.symbol);
case T___extension__:
STORAGE_CLASSES
- TYPE_QUALIFIERS
- return !only_type_specifiers;
+ return !only_specifiers_qualifiers;
default:
return false;
declaration->type = specifiers->type;
declaration->declared_storage_class = specifiers->declared_storage_class;
declaration->source_position = specifiers->source_position;
- declaration->modifiers = specifiers->decl_modifiers;
+ declaration->decl_modifiers = specifiers->decl_modifiers;
if (declaration->declared_storage_class != STORAGE_CLASS_NONE) {
warningf(&declaration->source_position,
static void parse_kr_declaration_list(declaration_t *declaration)
{
type_t *type = skip_typeref(declaration->type);
- if(!is_type_function(type))
+ if (!is_type_function(type))
return;
- if(!type->function.kr_style_parameters)
+ if (!type->function.kr_style_parameters)
return;
/* push function parameters */
set_scope(&declaration->scope);
declaration_t *parameter = declaration->scope.declarations;
- for( ; parameter != NULL; parameter = parameter->next) {
+ for ( ; parameter != NULL; parameter = parameter->next) {
assert(parameter->parent_scope == NULL);
parameter->parent_scope = scope;
environment_push(parameter);
}
/* parse declaration list */
- while(is_declaration_specifier(&token, false)) {
+ while (is_declaration_specifier(&token, false)) {
parse_declaration(finished_kr_declaration);
}
/* update function type */
type_t *new_type = duplicate_type(type);
- new_type->function.kr_style_parameters = false;
function_parameter_t *parameters = NULL;
function_parameter_t *last_parameter = NULL;
}
last_parameter = function_parameter;
}
+
+ /* § 6.9.1.7: A K&R style parameter list does NOT act as a function
+ * prototype */
new_type->function.parameters = parameters;
+ new_type->function.unspecified_parameters = true;
type = typehash_insert(new_type);
if(type != new_type) {
parse_kr_declaration_list(ndeclaration);
if(token.type != '{') {
- parse_error_expected("while parsing function definition", '{', 0);
+ parse_error_expected("while parsing function definition", '{', NULL);
eat_until_matching_token(';');
return;
}
/* § 6.7.5.3 (14) a function definition with () means no
* parameters (and not unspecified parameters) */
- if(type->function.unspecified_parameters) {
+ if(type->function.unspecified_parameters
+ && type->function.parameters == NULL
+ && !type->function.kr_style_parameters) {
type_t *duplicate = duplicate_type(type);
duplicate->function.unspecified_parameters = false;
declaration_t *old_current_function = current_function;
current_function = declaration;
- declaration->init.statement = parse_compound_statement();
+ declaration->init.statement = parse_compound_statement(false);
first_err = true;
check_labels();
check_declarations();
environment_pop_to(top);
}
-static type_t *make_bitfield_type(type_t *base, expression_t *size,
+static type_t *make_bitfield_type(type_t *base_type, expression_t *size,
source_position_t *source_position)
{
- type_t *type = allocate_type_zero(TYPE_BITFIELD, source_position);
- type->bitfield.base = base;
- type->bitfield.size = size;
+ type_t *type = allocate_type_zero(TYPE_BITFIELD, source_position);
+
+ type->bitfield.base_type = base_type;
+ type->bitfield.size = size;
return type;
}
declaration->declared_storage_class = STORAGE_CLASS_NONE;
declaration->storage_class = STORAGE_CLASS_NONE;
declaration->source_position = source_position;
- declaration->modifiers = specifiers->decl_modifiers;
+ declaration->decl_modifiers = specifiers->decl_modifiers;
declaration->type = type;
} else {
declaration = parse_declarator(specifiers,/*may_be_abstract=*/true);
declaration->type = type;
declaration->symbol = symbol;
declaration->source_position = *source_position;
- declaration->parent_scope = global_scope;
-
- scope_t *old_scope = scope;
- set_scope(global_scope);
-
- environment_push(declaration);
- /* prepends the declaration to the global declarations list */
- declaration->next = scope->declarations;
- scope->declarations = declaration;
- assert(scope == global_scope);
- set_scope(old_scope);
+ bool strict_prototypes_old = warning.strict_prototypes;
+ warning.strict_prototypes = false;
+ record_declaration(declaration);
+ warning.strict_prototypes = strict_prototypes_old;
return declaration;
}
return result;
}
+static type_t *make_function_0_type(type_t *return_type)
+{
+ type_t *type = allocate_type_zero(TYPE_FUNCTION, &builtin_source_position);
+ type->function.return_type = return_type;
+ type->function.parameters = NULL;
+
+ type_t *result = typehash_insert(type);
+ if(result != type) {
+ free_type(type);
+ }
+
+ return result;
+}
+
/**
* Creates a function type for some function like builtins.
*
switch(symbol->ID) {
case T___builtin_alloca:
return make_function_1_type(type_void_ptr, type_size_t);
+ case T___builtin_huge_val:
+ return make_function_0_type(type_double);
case T___builtin_nan:
return make_function_1_type(type_double, type_char_ptr);
case T___builtin_nanf:
if(is_type_array(type)) {
array_type_t *array_type = &type->array;
type_t *element_type = array_type->element_type;
- unsigned qualifiers = array_type->type.qualifiers;
+ unsigned qualifiers = array_type->base.qualifiers;
return make_pointer_type(element_type, qualifiers);
}
expression_t *expression = allocate_expression_zero(EXPR_REFERENCE);
reference_expression_t *ref = &expression->reference;
- ref->symbol = token.v.symbol;
+ symbol_t *const symbol = token.v.symbol;
- declaration_t *declaration = get_declaration(ref->symbol, NAMESPACE_NORMAL);
+ declaration_t *declaration = get_declaration(symbol, NAMESPACE_NORMAL);
source_position_t source_position = token.source_position;
next_token();
/* an implicitly defined function */
if (warning.implicit_function_declaration) {
warningf(HERE, "implicit declaration of function '%Y'",
- ref->symbol);
+ symbol);
}
- declaration = create_implicit_function(ref->symbol,
+ declaration = create_implicit_function(symbol,
&source_position);
} else {
- errorf(HERE, "unknown symbol '%Y' found.", ref->symbol);
+ errorf(HERE, "unknown symbol '%Y' found.", symbol);
return create_invalid_expression();
}
}
{
expression_t *expression = allocate_expression_zero(EXPR_STATEMENT);
- statement_t *statement = parse_compound_statement();
+ statement_t *statement = parse_compound_statement(true);
expression->statement.statement = statement;
expression->base.source_position = statement->base.source_position;
if(token.type != T_IDENTIFIER) {
parse_error_expected("while parsing member designator",
- T_IDENTIFIER, 0);
+ T_IDENTIFIER, NULL);
return NULL;
}
result->symbol = token.v.symbol;
next_token();
if(token.type != T_IDENTIFIER) {
parse_error_expected("while parsing member designator",
- T_IDENTIFIER, 0);
+ T_IDENTIFIER, NULL);
return NULL;
}
designator_t *designator = allocate_ast_zero(sizeof(result[0]));
case T___builtin_nan:
case T___builtin_nand:
case T___builtin_nanf:
+ case T___builtin_huge_val:
case T___builtin_va_end: return parse_builtin_symbol();
case T___builtin_isgreater:
case T___builtin_isgreaterequal:
rem_anchor_token(']');
if(token.type != ']') {
- parse_error_expected("Problem while parsing array access", ']', 0);
+ parse_error_expected("Problem while parsing array access", ']', NULL);
return expression;
}
next_token();
return expression;
}
-static expression_t *parse_typeprop(expression_kind_t kind, unsigned precedence)
+static expression_t *parse_typeprop(expression_kind_t const kind,
+ source_position_t const pos,
+ unsigned const precedence)
{
expression_t *tp_expression = allocate_expression_zero(kind);
- tp_expression->base.type = type_size_t;
+ tp_expression->base.type = type_size_t;
+ tp_expression->base.source_position = pos;
- if(token.type == '(' && is_declaration_specifier(look_ahead(1), true)) {
+ char const* const what = kind == EXPR_SIZEOF ? "sizeof" : "alignof";
+
+ if (token.type == '(' && is_declaration_specifier(look_ahead(1), true)) {
next_token();
add_anchor_token(')');
- tp_expression->typeprop.type = parse_typename();
+ type_t* const orig_type = parse_typename();
+ tp_expression->typeprop.type = orig_type;
+
+ type_t const* const type = skip_typeref(orig_type);
+ char const* const wrong_type =
+ is_type_incomplete(type) ? "incomplete" :
+ type->kind == TYPE_FUNCTION ? "function designator" :
+ type->kind == TYPE_BITFIELD ? "bitfield" :
+ NULL;
+ if (wrong_type != NULL) {
+ errorf(&pos, "operand of %s expression must not be %s type '%T'",
+ what, wrong_type, type);
+ }
+
rem_anchor_token(')');
expect(')');
} else {
expression_t *expression = parse_sub_expression(precedence);
- expression->base.type = revert_automatic_type_conversion(expression);
+
+ type_t* const orig_type = revert_automatic_type_conversion(expression);
+ expression->base.type = orig_type;
+
+ type_t const* const type = skip_typeref(orig_type);
+ char const* const wrong_type =
+ is_type_incomplete(type) ? "incomplete" :
+ type->kind == TYPE_FUNCTION ? "function designator" :
+ type->kind == TYPE_BITFIELD ? "bitfield" :
+ NULL;
+ if (wrong_type != NULL) {
+ errorf(&pos, "operand of %s expression must not be expression of %s type '%T'", what, wrong_type, type);
+ }
tp_expression->typeprop.type = expression->base.type;
tp_expression->typeprop.tp_expression = expression;
static expression_t *parse_sizeof(unsigned precedence)
{
+ source_position_t pos = *HERE;
eat(T_sizeof);
- return parse_typeprop(EXPR_SIZEOF, precedence);
+ return parse_typeprop(EXPR_SIZEOF, pos, precedence);
}
static expression_t *parse_alignof(unsigned precedence)
{
+ source_position_t pos = *HERE;
eat(T___alignof__);
- return parse_typeprop(EXPR_SIZEOF, precedence);
+ return parse_typeprop(EXPR_ALIGNOF, pos, precedence);
}
static expression_t *parse_select_expression(unsigned precedence,
expression_t *select = allocate_expression_zero(EXPR_SELECT);
select->select.compound = compound;
- if(token.type != T_IDENTIFIER) {
- parse_error_expected("while parsing select", T_IDENTIFIER, 0);
+ if (token.type != T_IDENTIFIER) {
+ parse_error_expected("while parsing select", T_IDENTIFIER, NULL);
return select;
}
symbol_t *symbol = token.v.symbol;
type_t *const type = skip_typeref(orig_type);
type_t *type_left = type;
- if(is_pointer) {
+ if (is_pointer) {
if (!is_type_pointer(type)) {
if (is_type_valid(type)) {
errorf(HERE, "left hand side of '->' is not a pointer, but '%T'", orig_type);
declaration_t *const declaration = type_left->compound.declaration;
- if(!declaration->init.is_defined) {
+ if (!declaration->init.complete) {
errorf(HERE, "request for member '%Y' of incomplete type '%T'",
symbol, type_left);
return create_invalid_expression();
}
declaration_t *iter = find_compound_entry(declaration, symbol);
- if(iter == NULL) {
+ if (iter == NULL) {
errorf(HERE, "'%T' has no member named '%Y'", orig_type, symbol);
return create_invalid_expression();
}
select->select.compound_entry = iter;
select->base.type = expression_type;
- if(expression_type->kind == TYPE_BITFIELD) {
- expression_t *extract
- = allocate_expression_zero(EXPR_UNARY_BITFIELD_EXTRACT);
- extract->unary.value = select;
- extract->base.type = expression_type->bitfield.base;
-
- return extract;
+ type_t *skipped = skip_typeref(iter->type);
+ if (skipped->kind == TYPE_BITFIELD) {
+ select->base.type = skipped->bitfield.base_type;
}
return select;
/* TODO non-arithmetic types */
if(is_type_arithmetic(type_left) && is_type_arithmetic(type_right)) {
+ /* test for signed vs unsigned compares */
if (warning.sign_compare &&
(expression->base.kind != EXPR_BINARY_EQUAL &&
expression->base.kind != EXPR_BINARY_NOTEQUAL) &&
(is_type_signed(type_left) != is_type_signed(type_right))) {
+
+ /* check if 1 of the operands is a constant, in this case we just
+ * check wether we can safely represent the resulting constant in
+ * the type of the other operand. */
+ expression_t *const_expr = NULL;
+ expression_t *other_expr = NULL;
+
+ if(is_constant_expression(left)) {
+ const_expr = left;
+ other_expr = right;
+ } else if(is_constant_expression(right)) {
+ const_expr = right;
+ other_expr = left;
+ }
+
+ if(const_expr != NULL) {
+ type_t *other_type = skip_typeref(other_expr->base.type);
+ long val = fold_constant(const_expr);
+ /* TODO: check if val can be represented by other_type */
+ (void) other_type;
+ (void) val;
+ }
warningf(&expression->base.source_position,
"comparison between signed and unsigned");
}
expression->base.type = type_int;
}
+/**
+ * Checks if a compound type has constant fields.
+ */
+static bool has_const_fields(const compound_type_t *type)
+{
+ const scope_t *scope = &type->declaration->scope;
+ const declaration_t *declaration = scope->declarations;
+
+ for (; declaration != NULL; declaration = declaration->next) {
+ if (declaration->namespc != NAMESPACE_NORMAL)
+ continue;
+
+ const type_t *decl_type = skip_typeref(declaration->type);
+ if (decl_type->base.qualifiers & TYPE_QUALIFIER_CONST)
+ return true;
+ }
+ /* TODO */
+ return false;
+}
+
+static bool is_valid_assignment_lhs(expression_t const* const left)
+{
+ type_t *const orig_type_left = revert_automatic_type_conversion(left);
+ type_t *const type_left = skip_typeref(orig_type_left);
+
+ switch (left->kind) {
+ case EXPR_REFERENCE:
+ case EXPR_ARRAY_ACCESS:
+ case EXPR_SELECT:
+ case EXPR_UNARY_DEREFERENCE:
+ break;
+
+ default:
+ errorf(HERE, "left hand side '%E' of assignment is not an lvalue", left);
+ return false;
+ }
+
+ if (is_type_array(type_left)) {
+ errorf(HERE, "cannot assign to arrays ('%E')", left);
+ return false;
+ }
+ if (type_left->base.qualifiers & TYPE_QUALIFIER_CONST) {
+ errorf(HERE, "assignment to readonly location '%E' (type '%T')", left,
+ orig_type_left);
+ return false;
+ }
+ if (is_type_incomplete(type_left)) {
+ errorf(HERE, "left-hand side '%E' of assignment has incomplete type '%T'",
+ left, orig_type_left);
+ return false;
+ }
+ if (is_type_compound(type_left) && has_const_fields(&type_left->compound)) {
+ errorf(HERE, "cannot assign to '%E' because compound type '%T' has readonly fields",
+ left, orig_type_left);
+ return false;
+ }
+
+ return true;
+}
+
static void semantic_arithmetic_assign(binary_expression_t *expression)
{
expression_t *left = expression->left;
type_t *orig_type_left = left->base.type;
type_t *orig_type_right = right->base.type;
+ if (!is_valid_assignment_lhs(left))
+ return;
+
type_t *type_left = skip_typeref(orig_type_left);
type_t *type_right = skip_typeref(orig_type_right);
type_t *const type_left = skip_typeref(orig_type_left);
type_t *const type_right = skip_typeref(orig_type_right);
+ if (!is_valid_assignment_lhs(left))
+ return;
+
if (is_type_arithmetic(type_left) && is_type_arithmetic(type_right)) {
/* combined instructions are tricky. We can't create an implicit cast on
* the left side, because we need the uncasted form for the store.
expression->base.type = type_int;
}
-/**
- * Checks if a compound type has constant fields.
- */
-static bool has_const_fields(const compound_type_t *type)
-{
- const scope_t *scope = &type->declaration->scope;
- const declaration_t *declaration = scope->declarations;
-
- for (; declaration != NULL; declaration = declaration->next) {
- if (declaration->namespc != NAMESPACE_NORMAL)
- continue;
-
- const type_t *decl_type = skip_typeref(declaration->type);
- if (decl_type->base.qualifiers & TYPE_QUALIFIER_CONST)
- return true;
- }
- /* TODO */
- return false;
-}
-
/**
* Check the semantic restrictions of a binary assign expression.
*/
type_t *type_left = revert_automatic_type_conversion(left);
type_left = skip_typeref(orig_type_left);
- /* must be a modifiable lvalue */
- if (is_type_array(type_left)) {
- errorf(HERE, "cannot assign to arrays ('%E')", left);
+ if (!is_valid_assignment_lhs(left))
return;
- }
- if(type_left->base.qualifiers & TYPE_QUALIFIER_CONST) {
- errorf(HERE, "assignment to readonly location '%E' (type '%T')", left,
- orig_type_left);
- return;
- }
- if(is_type_incomplete(type_left)) {
- errorf(HERE,
- "left-hand side of assignment '%E' has incomplete type '%T'",
- left, orig_type_left);
- return;
- }
- if(is_type_compound(type_left) && has_const_fields(&type_left->compound)) {
- errorf(HERE, "cannot assign to '%E' because compound type '%T' has readonly fields",
- left, orig_type_left);
- return;
- }
type_t *const res_type = semantic_assign(orig_type_left, expression->right,
"assignment", &left->base.source_position);
case EXPR_UNARY_CAST_IMPLICIT: return true;
case EXPR_UNARY_ASSUME: return true;
- case EXPR_UNARY_BITFIELD_EXTRACT: return false;
case EXPR_BINARY_ADD: return false;
case EXPR_BINARY_SUB: return false;
eat('[');
if(token.type != T_IDENTIFIER) {
parse_error_expected("while parsing asm constraint",
- T_IDENTIFIER, 0);
+ T_IDENTIFIER, NULL);
return NULL;
}
constraint->symbol = token.v.symbol;
eat(T_goto);
if(token.type != T_IDENTIFIER) {
- parse_error_expected("while parsing goto", T_IDENTIFIER, 0);
+ parse_error_expected("while parsing goto", T_IDENTIFIER, NULL);
eat_statement();
return NULL;
}
statement_t *statement;
if (current_loop == NULL) {
errorf(HERE, "continue statement not within loop");
- statement = NULL;
+ statement = create_invalid_statement();
} else {
statement = allocate_statement_zero(STATEMENT_CONTINUE);
statement_t *statement;
if (current_switch == NULL && current_loop == NULL) {
errorf(HERE, "break statement not within loop or switch");
- statement = NULL;
+ statement = create_invalid_statement();
} else {
statement = allocate_statement_zero(STATEMENT_BREAK);
return create_invalid_statement();
}
+/**
+ * Parse a __leave statement.
+ */
+static statement_t *parse_leave(void)
+{
+ statement_t *statement;
+ if (current_try == NULL) {
+ errorf(HERE, "__leave statement not within __try");
+ statement = create_invalid_statement();
+ } else {
+ statement = allocate_statement_zero(STATEMENT_LEAVE);
+
+ statement->base.source_position = token.source_position;
+ }
+
+ eat(T___leave);
+ expect(';');
+
+ return statement;
+end_error:
+ return create_invalid_statement();
+}
+
/**
* Check if a given declaration represents a local variable.
*/
expression_t *const expr = parse_expression();
statement->expression.expression = expr;
- if (warning.unused_value && !expression_has_effect(expr)) {
- warningf(&expr->base.source_position, "statement has no effect");
- }
-
expect(';');
return statement;
return create_invalid_statement();
}
+/**
+ * Parse a microsoft __try { } __finally { } or
+ * __try{ } __except() { }
+ */
+static statement_t *parse_ms_try_statment(void) {
+ statement_t *statement = allocate_statement_zero(STATEMENT_MS_TRY);
+
+ statement->base.source_position = token.source_position;
+ eat(T___try);
+
+ ms_try_statement_t *rem = current_try;
+ current_try = &statement->ms_try;
+ statement->ms_try.try_statement = parse_compound_statement(false);
+ current_try = rem;
+
+ if(token.type == T___except) {
+ eat(T___except);
+ expect('(');
+ add_anchor_token(')');
+ expression_t *const expr = parse_expression();
+ type_t * type = skip_typeref(expr->base.type);
+ if (is_type_integer(type)) {
+ type = promote_integer(type);
+ } else if (is_type_valid(type)) {
+ errorf(&expr->base.source_position,
+ "__expect expression is not an integer, but '%T'", type);
+ type = type_error_type;
+ }
+ statement->ms_try.except_expression = create_implicit_cast(expr, type);
+ rem_anchor_token(')');
+ expect(')');
+ statement->ms_try.final_statement = parse_compound_statement(false);
+ } else if(token.type == T__finally) {
+ eat(T___finally);
+ statement->ms_try.final_statement = parse_compound_statement(false);
+ } else {
+ parse_error_expected("while parsing __try statement", T___except, T___finally, NULL);
+ return create_invalid_statement();
+ }
+ return statement;
+end_error:
+ return create_invalid_statement();
+}
+
/**
* Parse a statement.
+ * There's also parse_statement() which additionally checks for
+ * "statement has no effect" warnings
*/
-static statement_t *parse_statement(void)
+static statement_t *intern_parse_statement(void)
{
- statement_t *statement = NULL;
+ statement_t *statement = NULL;
/* declaration or statement */
add_anchor_token(';');
break;
case '{':
- statement = parse_compound_statement();
+ statement = parse_compound_statement(false);
break;
case T_if:
statement = parse_break();
break;
+ case T___leave:
+ statement = parse_leave();
+ break;
+
case T_return:
statement = parse_return();
break;
statement = parse_declaration_statement();
break;
+ case T___try:
+ statement = parse_ms_try_statment();
+ break;
+
default:
statement = parse_expression_statement();
break;
return statement;
}
+/**
+ * parse a statement and emits "statement has no effect" warning if needed
+ * (This is really a wrapper around intern_parse_statement with check for 1
+ * single warning. It is needed, because for statement expressions we have
+ * to avoid the warning on the last statement)
+ */
+static statement_t *parse_statement(void)
+{
+ statement_t *statement = intern_parse_statement();
+
+ if(statement->kind == STATEMENT_EXPRESSION && warning.unused_value) {
+ expression_t *expression = statement->expression.expression;
+ if(!expression_has_effect(expression)) {
+ warningf(&expression->base.source_position,
+ "statement has no effect");
+ }
+ }
+
+ return statement;
+}
+
/**
* Parse a compound statement.
*/
-static statement_t *parse_compound_statement(void)
+static statement_t *parse_compound_statement(bool inside_expression_statement)
{
statement_t *statement = allocate_statement_zero(STATEMENT_COMPOUND);
statement_t *last_statement = NULL;
while(token.type != '}' && token.type != T_EOF) {
- statement_t *sub_statement = parse_statement();
+ statement_t *sub_statement = intern_parse_statement();
if(is_invalid_statement(sub_statement)) {
/* an error occurred. if we are at an anchor, return */
if(at_anchor())
"end of file while looking for closing '}'");
}
+ /* look over all statements again to produce no effect warnings */
+ if(warning.unused_value) {
+ statement_t *sub_statement = statement->compound.statements;
+ for( ; sub_statement != NULL; sub_statement = sub_statement->base.next) {
+ if(sub_statement->kind != STATEMENT_EXPRESSION)
+ continue;
+ /* don't emit a warning for the last expression in an expression
+ * statement as it has always an effect */
+ if(inside_expression_statement && sub_statement->base.next == NULL)
+ continue;
+
+ expression_t *expression = sub_statement->expression.expression;
+ if(!expression_has_effect(expression)) {
+ warningf(&expression->base.source_position,
+ "statement has no effect");
+ }
+ }
+ }
+
end_error:
rem_anchor_token('}');
assert(scope == &statement->compound.scope);