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|
/*
* Symbol lookup and handling.
*
* Copyright (C) 2003 Transmeta Corp.
* 2003-2004 Linus Torvalds
*
* Licensed under the Open Software License version 1.1
*/
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include "lib.h"
#include "allocate.h"
#include "token.h"
#include "parse.h"
#include "symbol.h"
#include "scope.h"
#include "expression.h"
#include "target.h"
/*
* Secondary symbol list for stuff that needs to be output because it
* was used.
*/
struct symbol_list *translation_unit_used_list = NULL;
/*
* If the symbol is an inline symbol, add it to the list of symbols to parse
*/
void access_symbol(struct symbol *sym)
{
if (sym->ctype.modifiers & MOD_INLINE) {
if (!(sym->ctype.modifiers & MOD_ACCESSED)) {
add_symbol(&translation_unit_used_list, sym);
sym->ctype.modifiers |= MOD_ACCESSED;
}
}
}
struct symbol *lookup_symbol(struct ident *ident, enum namespace ns)
{
struct symbol *sym;
for (sym = ident->symbols; sym; sym = sym->next_id) {
if (sym->namespace & ns) {
sym->used = 1;
return sym;
}
}
return NULL;
}
struct context *alloc_context(void)
{
return __alloc_context(0);
}
struct symbol *alloc_symbol(struct position pos, int type)
{
struct symbol *sym = __alloc_symbol(0);
sym->type = type;
sym->pos = pos;
sym->endpos.type = 0;
return sym;
}
struct struct_union_info {
unsigned long max_align;
unsigned long bit_size;
int align_size;
};
/*
* Unions are fairly easy to lay out ;)
*/
static void lay_out_union(struct symbol *sym, struct struct_union_info *info)
{
examine_symbol_type(sym);
// Unnamed bitfields do not affect alignment.
if (sym->ident || !is_bitfield_type(sym)) {
if (sym->ctype.alignment > info->max_align)
info->max_align = sym->ctype.alignment;
}
if (sym->bit_size > info->bit_size)
info->bit_size = sym->bit_size;
sym->offset = 0;
}
static int bitfield_base_size(struct symbol *sym)
{
if (sym->type == SYM_NODE)
sym = sym->ctype.base_type;
if (sym->type == SYM_BITFIELD)
sym = sym->ctype.base_type;
return sym->bit_size;
}
/*
* Structures are a bit more interesting to lay out
*/
static void lay_out_struct(struct symbol *sym, struct struct_union_info *info)
{
unsigned long bit_size, align_bit_mask;
int base_size;
examine_symbol_type(sym);
// Unnamed bitfields do not affect alignment.
if (sym->ident || !is_bitfield_type(sym)) {
if (sym->ctype.alignment > info->max_align)
info->max_align = sym->ctype.alignment;
}
bit_size = info->bit_size;
base_size = sym->bit_size;
/*
* Unsized arrays cause us to not align the resulting
* structure size
*/
if (base_size < 0) {
info->align_size = 0;
base_size = 0;
}
align_bit_mask = bytes_to_bits(sym->ctype.alignment) - 1;
/*
* Bitfields have some very special rules..
*/
if (is_bitfield_type (sym)) {
unsigned long bit_offset = bit_size & align_bit_mask;
int room = bitfield_base_size(sym) - bit_offset;
// Zero-width fields just fill up the unit.
int width = base_size ? : (bit_offset ? room : 0);
if (width > room) {
bit_size = (bit_size + align_bit_mask) & ~align_bit_mask;
bit_offset = 0;
}
sym->offset = bits_to_bytes(bit_size - bit_offset);
sym->bit_offset = bit_offset;
sym->ctype.base_type->bit_offset = bit_offset;
info->bit_size = bit_size + width;
// warning (sym->pos, "bitfield: offset=%d:%d size=:%d", sym->offset, sym->bit_offset, width);
return;
}
/*
* Otherwise, just align it right and add it up..
*/
bit_size = (bit_size + align_bit_mask) & ~align_bit_mask;
sym->offset = bits_to_bytes(bit_size);
info->bit_size = bit_size + base_size;
// warning (sym->pos, "regular: offset=%d", sym->offset);
}
static struct symbol * examine_struct_union_type(struct symbol *sym, int advance)
{
struct struct_union_info info = {
.max_align = 1,
.bit_size = 0,
.align_size = 1
};
unsigned long bit_size, bit_align;
void (*fn)(struct symbol *, struct struct_union_info *);
struct symbol *member;
fn = advance ? lay_out_struct : lay_out_union;
FOR_EACH_PTR(sym->symbol_list, member) {
fn(member, &info);
} END_FOR_EACH_PTR(member);
if (!sym->ctype.alignment)
sym->ctype.alignment = info.max_align;
bit_size = info.bit_size;
if (info.align_size) {
bit_align = bytes_to_bits(sym->ctype.alignment)-1;
bit_size = (bit_size + bit_align) & ~bit_align;
}
sym->bit_size = bit_size;
return sym;
}
static struct symbol *examine_base_type(struct symbol *sym)
{
struct symbol *base_type;
/* Check the base type */
base_type = examine_symbol_type(sym->ctype.base_type);
if (!base_type || base_type->type == SYM_PTR)
return base_type;
sym->ctype.as |= base_type->ctype.as;
sym->ctype.modifiers |= base_type->ctype.modifiers & MOD_PTRINHERIT;
concat_ptr_list((struct ptr_list *)base_type->ctype.contexts,
(struct ptr_list **)&sym->ctype.contexts);
if (base_type->type == SYM_NODE) {
base_type = base_type->ctype.base_type;
sym->ctype.base_type = base_type;
}
return base_type;
}
static struct symbol * examine_array_type(struct symbol *sym)
{
struct symbol *base_type = examine_base_type(sym);
unsigned long bit_size, alignment;
if (!base_type)
return sym;
bit_size = base_type->bit_size * get_expression_value(sym->array_size);
if (!sym->array_size || sym->array_size->type != EXPR_VALUE)
bit_size = -1;
alignment = base_type->ctype.alignment;
if (!sym->ctype.alignment)
sym->ctype.alignment = alignment;
sym->bit_size = bit_size;
return sym;
}
static struct symbol *examine_bitfield_type(struct symbol *sym)
{
struct symbol *base_type = examine_base_type(sym);
unsigned long bit_size, alignment, modifiers;
if (!base_type)
return sym;
bit_size = base_type->bit_size;
if (sym->bit_size > bit_size)
warning(sym->pos, "impossible field-width, %d, for this type", sym->bit_size);
alignment = base_type->ctype.alignment;
if (!sym->ctype.alignment)
sym->ctype.alignment = alignment;
modifiers = base_type->ctype.modifiers;
/* Bitfields are unsigned, unless the base type was explicitly signed */
if (!(modifiers & MOD_EXPLICITLY_SIGNED))
modifiers = (modifiers & ~MOD_SIGNED) | MOD_UNSIGNED;
sym->ctype.modifiers |= modifiers & MOD_SIGNEDNESS;
return sym;
}
/*
* "typeof" will have to merge the types together
*/
void merge_type(struct symbol *sym, struct symbol *base_type)
{
sym->ctype.as |= base_type->ctype.as;
sym->ctype.modifiers |= (base_type->ctype.modifiers & ~MOD_STORAGE);
concat_ptr_list((struct ptr_list *)base_type->ctype.contexts,
(struct ptr_list **)&sym->ctype.contexts);
sym->ctype.base_type = base_type->ctype.base_type;
if (sym->ctype.base_type->type == SYM_NODE)
merge_type(sym, sym->ctype.base_type);
}
static int count_array_initializer(struct symbol *t, struct expression *expr)
{
int nr = 0;
int is_char = 0;
/*
* Arrays of character types are special; they can be initialized by
* string literal _or_ by string literal in braces. The latter means
* that with T x[] = {<string literal>} number of elements in x depends
* on T - if it's a character type, we get the length of string literal
* (including NUL), otherwise we have one element here.
*/
if (t->ctype.base_type == &int_type && t->ctype.modifiers & MOD_CHAR)
is_char = 1;
switch (expr->type) {
case EXPR_INITIALIZER: {
struct expression *entry;
int count = 0;
int str_len = 0;
FOR_EACH_PTR(expr->expr_list, entry) {
count++;
switch (entry->type) {
case EXPR_INDEX:
if (entry->idx_to >= nr)
nr = entry->idx_to+1;
break;
case EXPR_STRING:
if (is_char)
str_len = entry->string->length;
default:
nr++;
}
} END_FOR_EACH_PTR(entry);
if (count == 1 && str_len)
nr = str_len;
break;
}
case EXPR_STRING:
if (is_char)
nr = expr->string->length;
default:
break;
}
return nr;
}
static struct symbol * examine_node_type(struct symbol *sym)
{
struct symbol *base_type = examine_base_type(sym);
int bit_size;
unsigned long alignment, modifiers;
/* SYM_NODE - figure out what the type of the node was.. */
modifiers = sym->ctype.modifiers;
bit_size = 0;
alignment = 0;
if (!base_type)
return sym;
bit_size = base_type->bit_size;
alignment = base_type->ctype.alignment;
/* Pick up signedness information into the node */
sym->ctype.modifiers |= (MOD_SIGNEDNESS & base_type->ctype.modifiers);
if (!sym->ctype.alignment)
sym->ctype.alignment = alignment;
/* Unsized array? The size might come from the initializer.. */
if (bit_size < 0 && base_type->type == SYM_ARRAY && sym->initializer) {
struct symbol *node_type = base_type->ctype.base_type;
int count = count_array_initializer(node_type, sym->initializer);
if (node_type && node_type->bit_size >= 0)
bit_size = node_type->bit_size * count;
}
sym->bit_size = bit_size;
return sym;
}
static struct symbol *examine_enum_type(struct symbol *sym)
{
struct symbol *base_type = examine_base_type(sym);
sym->ctype.modifiers |= (base_type->ctype.modifiers & MOD_SIGNEDNESS);
sym->bit_size = bits_in_enum;
if (base_type->bit_size > sym->bit_size)
sym->bit_size = base_type->bit_size;
sym->ctype.alignment = enum_alignment;
if (base_type->ctype.alignment > sym->ctype.alignment)
sym->ctype.alignment = base_type->ctype.alignment;
return sym;
}
static struct symbol *examine_pointer_type(struct symbol *sym)
{
/*
* We need to set the pointer size first, and
* examine the thing we point to only afterwards.
* That's because this pointer type may end up
* being needed for the base type size evaluation.
*/
if (!sym->bit_size)
sym->bit_size = bits_in_pointer;
if (!sym->ctype.alignment)
sym->ctype.alignment = pointer_alignment;
return sym;
}
/*
* Fill in type size and alignment information for
* regular SYM_TYPE things.
*/
struct symbol *examine_symbol_type(struct symbol * sym)
{
if (!sym)
return sym;
/* Already done? */
if (sym->examined)
return sym;
sym->examined = 1;
switch (sym->type) {
case SYM_FN:
case SYM_NODE:
return examine_node_type(sym);
case SYM_ARRAY:
return examine_array_type(sym);
case SYM_STRUCT:
return examine_struct_union_type(sym, 1);
case SYM_UNION:
return examine_struct_union_type(sym, 0);
case SYM_PTR:
return examine_pointer_type(sym);
case SYM_ENUM:
return examine_enum_type(sym);
case SYM_BITFIELD:
return examine_bitfield_type(sym);
case SYM_BASETYPE:
/* Size and alignment had better already be set up */
return sym;
case SYM_TYPEOF: {
struct symbol *base = evaluate_expression(sym->initializer);
if (base) {
if (is_bitfield_type(base))
warning(base->pos, "typeof applied to bitfield type");
if (base->type == SYM_NODE)
base = base->ctype.base_type;
sym->type = SYM_NODE;
sym->ctype.modifiers = 0;
sym->ctype.base_type = base;
return examine_node_type(sym);
}
break;
}
case SYM_PREPROCESSOR:
sparse_error(sym->pos, "ctype on preprocessor command? (%s)", show_ident(sym->ident));
return NULL;
case SYM_UNINITIALIZED:
sparse_error(sym->pos, "ctype on uninitialized symbol %p", sym);
return NULL;
case SYM_RESTRICT:
examine_base_type(sym);
return sym;
case SYM_FOULED:
examine_base_type(sym);
return sym;
default:
sparse_error(sym->pos, "Examining unknown symbol type %d", sym->type);
break;
}
return sym;
}
const char* get_type_name(enum type type)
{
const char *type_lookup[] = {
[SYM_UNINITIALIZED] = "uninitialized",
[SYM_PREPROCESSOR] = "preprocessor",
[SYM_BASETYPE] = "basetype",
[SYM_NODE] = "node",
[SYM_PTR] = "pointer",
[SYM_FN] = "function",
[SYM_ARRAY] = "array",
[SYM_STRUCT] = "struct",
[SYM_UNION] = "union",
[SYM_ENUM] = "enum",
[SYM_TYPEDEF] = "typedef",
[SYM_TYPEOF] = "typeof",
[SYM_MEMBER] = "member",
[SYM_BITFIELD] = "bitfield",
[SYM_LABEL] = "label",
[SYM_RESTRICT] = "restrict",
[SYM_FOULED] = "fouled",
[SYM_KEYWORD] = "keyword",
[SYM_BAD] = "bad"};
if (type <= SYM_BAD)
return type_lookup[type];
else
return NULL;
}
struct symbol *examine_pointer_target(struct symbol *sym)
{
return examine_base_type(sym);
}
static struct symbol_list *restr, *fouled;
void create_fouled(struct symbol *type)
{
if (type->bit_size < bits_in_int) {
struct symbol *new = alloc_symbol(type->pos, type->type);
*new = *type;
new->bit_size = bits_in_int;
new->type = SYM_FOULED;
new->ctype.base_type = type;
add_symbol(&restr, type);
add_symbol(&fouled, new);
}
}
struct symbol *befoul(struct symbol *type)
{
struct symbol *t1, *t2;
while (type->type == SYM_NODE)
type = type->ctype.base_type;
PREPARE_PTR_LIST(restr, t1);
PREPARE_PTR_LIST(fouled, t2);
for (;;) {
if (t1 == type)
return t2;
if (!t1)
break;
NEXT_PTR_LIST(t1);
NEXT_PTR_LIST(t2);
}
FINISH_PTR_LIST(t2);
FINISH_PTR_LIST(t1);
return NULL;
}
void check_declaration(struct symbol *sym)
{
int warned = 0;
struct symbol *next = sym;
while ((next = next->next_id) != NULL) {
if (next->namespace != sym->namespace)
continue;
if (sym->scope == next->scope) {
sym->same_symbol = next;
return;
}
if (sym->ctype.modifiers & next->ctype.modifiers & MOD_EXTERN) {
if ((sym->ctype.modifiers ^ next->ctype.modifiers) & MOD_INLINE)
continue;
sym->same_symbol = next;
return;
}
if (!Wshadow || warned)
continue;
if (get_sym_type(next) == SYM_FN)
continue;
warned = 1;
warning(sym->pos, "symbol '%s' shadows an earlier one", show_ident(sym->ident));
info(next->pos, "originally declared here");
}
}
void bind_symbol(struct symbol *sym, struct ident *ident, enum namespace ns)
{
struct scope *scope;
if (sym->bound) {
sparse_error(sym->pos, "internal error: symbol type already bound");
return;
}
if (ident->reserved && (ns & (NS_TYPEDEF | NS_STRUCT | NS_LABEL | NS_SYMBOL))) {
sparse_error(sym->pos, "Trying to use reserved word '%s' as identifier", show_ident(ident));
return;
}
sym->namespace = ns;
sym->next_id = ident->symbols;
ident->symbols = sym;
if (sym->ident && sym->ident != ident)
warning(sym->pos, "Symbol '%s' already bound", show_ident(sym->ident));
sym->ident = ident;
sym->bound = 1;
scope = block_scope;
if (ns == NS_SYMBOL && toplevel(scope)) {
unsigned mod = MOD_ADDRESSABLE | MOD_TOPLEVEL;
scope = global_scope;
if (sym->ctype.modifiers & MOD_STATIC ||
is_extern_inline(sym)) {
scope = file_scope;
mod = MOD_TOPLEVEL;
}
sym->ctype.modifiers |= mod;
}
if (ns == NS_MACRO)
scope = file_scope;
if (ns == NS_LABEL)
scope = function_scope;
bind_scope(sym, scope);
}
struct symbol *create_symbol(int stream, const char *name, int type, int namespace)
{
struct token *token = built_in_token(stream, name);
struct symbol *sym = alloc_symbol(token->pos, type);
bind_symbol(sym, token->ident, namespace);
return sym;
}
static int evaluate_to_integer(struct expression *expr)
{
expr->ctype = &int_ctype;
return 1;
}
static int evaluate_expect(struct expression *expr)
{
/* Should we evaluate it to return the type of the first argument? */
expr->ctype = &int_ctype;
return 1;
}
static int arguments_choose(struct expression *expr)
{
struct expression_list *arglist = expr->args;
struct expression *arg;
int i = 0;
FOR_EACH_PTR (arglist, arg) {
if (!evaluate_expression(arg))
return 0;
i++;
} END_FOR_EACH_PTR(arg);
if (i < 3) {
sparse_error(expr->pos,
"not enough arguments for __builtin_choose_expr");
return 0;
} if (i > 3) {
sparse_error(expr->pos,
"too many arguments for __builtin_choose_expr");
return 0;
}
return 1;
}
static int evaluate_choose(struct expression *expr)
{
struct expression_list *list = expr->args;
struct expression *arg, *args[3];
int n = 0;
/* there will be exactly 3; we'd already verified that */
FOR_EACH_PTR(list, arg) {
args[n++] = arg;
} END_FOR_EACH_PTR(arg);
*expr = get_expression_value(args[0]) ? *args[1] : *args[2];
return 1;
}
static int expand_expect(struct expression *expr, int cost)
{
struct expression *arg = first_ptr_list((struct ptr_list *) expr->args);
if (arg)
*expr = *arg;
return 0;
}
/*
* __builtin_warning() has type "int" and always returns 1,
* so that you can use it in conditionals or whatever
*/
static int expand_warning(struct expression *expr, int cost)
{
struct expression *arg;
struct expression_list *arglist = expr->args;
FOR_EACH_PTR (arglist, arg) {
/*
* Constant strings get printed out as a warning. By the
* time we get here, the EXPR_STRING has been fully
* evaluated, so by now it's an anonymous symbol with a
* string initializer.
*
* Just for the heck of it, allow any constant string
* symbol.
*/
if (arg->type == EXPR_SYMBOL) {
struct symbol *sym = arg->symbol;
if (sym->initializer && sym->initializer->type == EXPR_STRING) {
struct string *string = sym->initializer->string;
warning(expr->pos, "%*s", string->length-1, string->data);
}
continue;
}
/*
* Any other argument is a conditional. If it's
* non-constant, or it is false, we exit and do
* not print any warning.
*/
if (arg->type != EXPR_VALUE)
goto out;
if (!arg->value)
goto out;
} END_FOR_EACH_PTR(arg);
out:
expr->type = EXPR_VALUE;
expr->value = 1;
expr->taint = 0;
return 0;
}
static struct symbol_op constant_p_op = {
.evaluate = evaluate_to_integer,
.expand = expand_constant_p
};
static struct symbol_op safe_p_op = {
.evaluate = evaluate_to_integer,
.expand = expand_safe_p
};
static struct symbol_op warning_op = {
.evaluate = evaluate_to_integer,
.expand = expand_warning
};
static struct symbol_op expect_op = {
.evaluate = evaluate_expect,
.expand = expand_expect
};
static struct symbol_op choose_op = {
.evaluate = evaluate_choose,
.args = arguments_choose,
};
/*
* Builtin functions
*/
static struct symbol builtin_fn_type = { .type = SYM_FN /* , .variadic =1 */ };
static struct sym_init {
const char *name;
struct symbol *base_type;
unsigned int modifiers;
struct symbol_op *op;
} eval_init_table[] = {
{ "__builtin_constant_p", &builtin_fn_type, MOD_TOPLEVEL, &constant_p_op },
{ "__builtin_safe_p", &builtin_fn_type, MOD_TOPLEVEL, &safe_p_op },
{ "__builtin_warning", &builtin_fn_type, MOD_TOPLEVEL, &warning_op },
{ "__builtin_expect", &builtin_fn_type, MOD_TOPLEVEL, &expect_op },
{ "__builtin_choose_expr", &builtin_fn_type, MOD_TOPLEVEL, &choose_op },
{ NULL, NULL, 0 }
};
/*
* Abstract types
*/
struct symbol int_type,
fp_type;
/*
* C types (i.e. actual instances that the abstract types
* can map onto)
*/
struct symbol bool_ctype, void_ctype, type_ctype,
char_ctype, schar_ctype, uchar_ctype,
short_ctype, sshort_ctype, ushort_ctype,
int_ctype, sint_ctype, uint_ctype,
long_ctype, slong_ctype, ulong_ctype,
llong_ctype, sllong_ctype, ullong_ctype,
lllong_ctype, slllong_ctype, ulllong_ctype,
float_ctype, double_ctype, ldouble_ctype,
string_ctype, ptr_ctype, lazy_ptr_ctype,
incomplete_ctype, label_ctype, bad_ctype,
null_ctype;
struct symbol zero_int;
#define __INIT_IDENT(str, res) { .len = sizeof(str)-1, .name = str, .reserved = res }
#define __IDENT(n,str,res) \
struct ident n = __INIT_IDENT(str,res)
#include "ident-list.h"
void init_symbols(void)
{
int stream = init_stream("builtin", -1, includepath);
struct sym_init *ptr;
#define __IDENT(n,str,res) \
hash_ident(&n)
#include "ident-list.h"
init_parser(stream);
builtin_fn_type.variadic = 1;
for (ptr = eval_init_table; ptr->name; ptr++) {
struct symbol *sym;
sym = create_symbol(stream, ptr->name, SYM_NODE, NS_SYMBOL);
sym->ctype.base_type = ptr->base_type;
sym->ctype.modifiers = ptr->modifiers;
sym->op = ptr->op;
}
}
#define MOD_ESIGNED (MOD_SIGNED | MOD_EXPLICITLY_SIGNED)
#define MOD_LL (MOD_LONG | MOD_LONGLONG)
#define MOD_LLL MOD_LONGLONGLONG
static const struct ctype_declare {
struct symbol *ptr;
enum type type;
unsigned long modifiers;
int *bit_size;
int *maxalign;
struct symbol *base_type;
} ctype_declaration[] = {
{ &bool_ctype, SYM_BASETYPE, MOD_UNSIGNED, &bits_in_bool, &max_int_alignment, &int_type },
{ &void_ctype, SYM_BASETYPE, 0, NULL, NULL, NULL },
{ &type_ctype, SYM_BASETYPE, MOD_TYPE, NULL, NULL, NULL },
{ &incomplete_ctype,SYM_BASETYPE, 0, NULL, NULL, NULL },
{ &bad_ctype, SYM_BASETYPE, 0, NULL, NULL, NULL },
{ &char_ctype, SYM_BASETYPE, MOD_SIGNED | MOD_CHAR, &bits_in_char, &max_int_alignment, &int_type },
{ &schar_ctype, SYM_BASETYPE, MOD_ESIGNED | MOD_CHAR, &bits_in_char, &max_int_alignment, &int_type },
{ &uchar_ctype, SYM_BASETYPE, MOD_UNSIGNED | MOD_CHAR, &bits_in_char, &max_int_alignment, &int_type },
{ &short_ctype, SYM_BASETYPE, MOD_SIGNED | MOD_SHORT, &bits_in_short, &max_int_alignment, &int_type },
{ &sshort_ctype, SYM_BASETYPE, MOD_ESIGNED | MOD_SHORT, &bits_in_short, &max_int_alignment, &int_type },
{ &ushort_ctype, SYM_BASETYPE, MOD_UNSIGNED | MOD_SHORT, &bits_in_short, &max_int_alignment, &int_type },
{ &int_ctype, SYM_BASETYPE, MOD_SIGNED, &bits_in_int, &max_int_alignment, &int_type },
{ &sint_ctype, SYM_BASETYPE, MOD_ESIGNED, &bits_in_int, &max_int_alignment, &int_type },
{ &uint_ctype, SYM_BASETYPE, MOD_UNSIGNED, &bits_in_int, &max_int_alignment, &int_type },
{ &long_ctype, SYM_BASETYPE, MOD_SIGNED | MOD_LONG, &bits_in_long, &max_int_alignment, &int_type },
{ &slong_ctype, SYM_BASETYPE, MOD_ESIGNED | MOD_LONG, &bits_in_long, &max_int_alignment, &int_type },
{ &ulong_ctype, SYM_BASETYPE, MOD_UNSIGNED | MOD_LONG, &bits_in_long, &max_int_alignment, &int_type },
{ &llong_ctype, SYM_BASETYPE, MOD_SIGNED | MOD_LL, &bits_in_longlong, &max_int_alignment, &int_type },
{ &sllong_ctype, SYM_BASETYPE, MOD_ESIGNED | MOD_LL, &bits_in_longlong, &max_int_alignment, &int_type },
{ &ullong_ctype, SYM_BASETYPE, MOD_UNSIGNED | MOD_LL, &bits_in_longlong, &max_int_alignment, &int_type },
{ &lllong_ctype, SYM_BASETYPE, MOD_SIGNED | MOD_LLL, &bits_in_longlonglong, &max_int_alignment, &int_type },
{ &slllong_ctype, SYM_BASETYPE, MOD_ESIGNED | MOD_LLL, &bits_in_longlonglong, &max_int_alignment, &int_type },
{ &ulllong_ctype, SYM_BASETYPE, MOD_UNSIGNED | MOD_LLL, &bits_in_longlonglong, &max_int_alignment, &int_type },
{ &float_ctype, SYM_BASETYPE, 0, &bits_in_float, &max_fp_alignment, &fp_type },
{ &double_ctype, SYM_BASETYPE, MOD_LONG, &bits_in_double, &max_fp_alignment, &fp_type },
{ &ldouble_ctype, SYM_BASETYPE, MOD_LONG | MOD_LONGLONG, &bits_in_longdouble, &max_fp_alignment, &fp_type },
{ &string_ctype, SYM_PTR, 0, &bits_in_pointer, &pointer_alignment, &char_ctype },
{ &ptr_ctype, SYM_PTR, 0, &bits_in_pointer, &pointer_alignment, &void_ctype },
{ &null_ctype, SYM_PTR, 0, &bits_in_pointer, &pointer_alignment, &void_ctype },
{ &label_ctype, SYM_PTR, 0, &bits_in_pointer, &pointer_alignment, &void_ctype },
{ &lazy_ptr_ctype, SYM_PTR, 0, &bits_in_pointer, &pointer_alignment, &void_ctype },
{ NULL, }
};
#undef MOD_LLL
#undef MOD_LL
#undef MOD_ESIGNED
void init_ctype(void)
{
const struct ctype_declare *ctype;
for (ctype = ctype_declaration ; ctype->ptr; ctype++) {
struct symbol *sym = ctype->ptr;
unsigned long bit_size = ctype->bit_size ? *ctype->bit_size : -1;
unsigned long maxalign = ctype->maxalign ? *ctype->maxalign : 0;
unsigned long alignment = bits_to_bytes(bit_size + bits_in_char - 1);
if (alignment > maxalign)
alignment = maxalign;
sym->type = ctype->type;
sym->bit_size = bit_size;
sym->ctype.alignment = alignment;
sym->ctype.base_type = ctype->base_type;
sym->ctype.modifiers = ctype->modifiers;
}
}
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