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#include "asn1c_internal.h"
#include "asn1c_misc.h"
#include <asn1fix_crange.h> /* constraint groker from libasn1fix */
#include <asn1fix_export.h> /* other exportable stuff from libasn1fix */
/*
* Checks that the given string is not a reserved C/C++ keyword.
* ISO/IEC 9899:1999 (C99), A.1.2
*/
static char *res_kwd[] = {
"const", "auto", "register", "volatile", "restrict", "extern",
"static", "inline",
"signed", "unsigned",
"void", "char", "short", "int", "long", "float", "double",
"enum", "union", "struct", "typedef", "class",
"switch", "case", "default", "break", "continue",
"if", "else", "do", "for", "while", "goto",
"sizeof", "return"
};
static int
reserved_keyword(const char *str) {
int i;
for(i = 0 ; i < sizeof(res_kwd)/sizeof(res_kwd[0]); i++) {
if(strcmp(str, res_kwd[i]) == 0)
return 1;
}
return 0;
}
/*
* Construct identifier from multiple parts.
* Convert unsafe characters to underscores.
*/
char *
asn1c_make_identifier(enum ami_flags_e flags, char *arg1, ...) {
static char *storage;
static int storage_size;
int nodelimiter = 0;
va_list ap;
char *str;
char *nextstr;
size_t size;
char *p;
if(arg1 == NULL)
return NULL;
/*
* Estimate the necessary storage size
*/
size = strlen(arg1);
va_start(ap, arg1);
while((str = va_arg(ap, char *)))
size += 1 + strlen(str);
va_end(ap);
/*
* Make sure we have this amount of storage.
*/
if(storage_size <= size) {
if(storage) free(storage);
storage = malloc(size + 1);
if(storage) {
storage_size = size;
} else {
storage_size = 0;
return NULL;
}
}
/*
* Fill-in the storage.
*/
va_start(ap, arg1);
str = arg1;
p = storage;
for(str = arg1; str; str = nextstr) {
int subst_made = 0;
nextstr = va_arg(ap, char *);
if(str[0] == ' ' && str[1] == '\0') {
*p++ = ' ';
nodelimiter = 1; /* No delimiter */
continue;
}
if(str != arg1 && !nodelimiter)
*p++ = '_'; /* Delimiter between tokens */
nodelimiter = 0;
/*
* If it is a single argument, check that it does not clash
* with C/C++ language keywords.
*/
if((flags & AMI_CHECK_RESERVED)
&& str == arg1 && !nextstr && reserved_keyword(str)) {
*p++ = toupper(*str++);
/* Fall through */
}
for(; *str; str++) {
if(isalnum(*str)) {
*p++ = *str;
subst_made = 0;
} else if(!subst_made++) {
if((flags & AMI_MASK_ONLY_SPACES)
&& !isspace(*str)) {
*p ++ = *str;
} else {
*p++ = '_';
}
}
}
}
va_end(ap);
*p = '\0';
assert((p - storage) <= storage_size);
return storage;
}
char *
asn1c_type_name(arg_t *arg, asn1p_expr_t *expr, enum tnfmt _format) {
asn1p_expr_t *top_parent;
char *typename;
/* Rewind to the topmost parent expression */
if((top_parent = expr->parent_expr))
while(top_parent->parent_expr)
top_parent = top_parent->parent_expr;
switch(expr->expr_type) {
case A1TC_REFERENCE:
typename = expr->reference->components[
expr->reference->comp_count-1].name;
if(typename[0] == '&') {
arg_t tmp = *arg;
/*
* This is a reference to a type defined in a class.
* Resolve it and use instead.
*/
tmp.expr = asn1f_class_access_ex(arg->asn, arg->mod,
arg->expr, expr->reference);
if(tmp.expr) return NULL;
tmp.mod = tmp.expr->module;
return asn1c_type_name(&tmp, tmp.expr, _format);
}
if(_format == TNF_RSAFE) {
asn1p_expr_t *terminal;
terminal = asn1f_find_terminal_type_ex(arg->asn, expr);
if(terminal && terminal->expr_type & ASN_CONSTR_MASK) {
typename = terminal->Identifier;
}
}
if(_format == TNF_CTYPE) {
/*
* If the component references the type itself,
* switch to a recursion-safe type naming
* ("struct foo" instead of "foo_t").
*/
asn1p_expr_t *terminal;
terminal = asn1f_find_terminal_type_ex(arg->asn, expr);
if(terminal && terminal == top_parent) {
_format = TNF_RSAFE;
}
}
break;
#if 0
case ASN_CONSTR_SEQUENCE_OF:
case ASN_CONSTR_SET_OF:
if(expr->Identifier) {
typename = expr->Identifier;
} else {
asn1p_expr_t *child;
child = TQ_FIRST(&(expr->members));
typename = asn1c_type_name(arg, child, _format);
if(typename)
return typename;
_format = TNF_SAFE;
typename = child->Identifier;
}
break;
#endif
case ASN_BASIC_INTEGER:
case ASN_BASIC_ENUMERATED:
case ASN_BASIC_REAL:
if((expr->expr_type == ASN_BASIC_REAL
&& (arg->flags & A1C_USE_NATIVE_TYPES))
|| asn1c_type_fits_long(arg, expr)) {
switch(_format) {
case TNF_CTYPE:
case TNF_RSAFE:
if(expr->expr_type == ASN_BASIC_REAL)
return "double";
else
return "long";
default: break;
}
switch(expr->expr_type) {
case ASN_BASIC_INTEGER:
return "NativeInteger";
case ASN_BASIC_ENUMERATED:
return "NativeEnumerated";
case ASN_BASIC_REAL:
return "NativeReal";
default: break;
}
}
/* Fall through */
default:
if(expr->expr_type
& (ASN_CONSTR_MASK | ASN_BASIC_MASK | ASN_STRING_MASK)) {
if(_format == TNF_RSAFE)
_format = TNF_CTYPE;
typename = ASN_EXPR_TYPE2STR(expr->expr_type);
} else {
_format = TNF_RSAFE;
typename = expr->Identifier;
}
}
switch(_format) {
case TNF_UNMODIFIED:
case TNF_INCLUDE:
return asn1c_make_identifier(AMI_MASK_ONLY_SPACES, typename, 0);
case TNF_SAFE:
return asn1c_make_identifier(0, typename, 0);
case TNF_CTYPE: /* C type */
return asn1c_make_identifier(0, typename, "t", 0);
case TNF_RSAFE: /* Recursion-safe type */
return asn1c_make_identifier(AMI_CHECK_RESERVED,
"struct", " ", typename, 0);
}
assert(!"unreachable");
return typename;
}
/*
* Check whether the specified INTEGER or ENUMERATED type can be represented
* using the generic 'long' type.
*/
enum asn1c_fitslong_e
asn1c_type_fits_long(arg_t *arg, asn1p_expr_t *expr) {
asn1cnst_range_t *range = 0;
asn1cnst_edge_t left;
asn1cnst_edge_t right;
asn1p_expr_t *v;
/*
* Since we don't know the sizeof(long) on the possible target platform
* which will be compiling the code generated by asn1c, let's play it
* simple: long's range is equal to or greater than int32_t.
*/
#define LEFTMIN INT32_MIN
#define RIGHTMAX INT32_MAX
/* Descend to the terminal type */
expr = asn1f_find_terminal_type_ex(arg->asn, expr);
if(expr == 0) return FL_NOTFIT;
/* The "fits into long" operation is relevant only for integer types */
switch(expr->expr_type) {
case ASN_BASIC_INTEGER:
case ASN_BASIC_ENUMERATED:
break;
default:
return FL_NOTFIT;
}
/*
* First, evaluate the range of explicitly given identifiers.
*/
TQ_FOR(v, &(expr->members), next) {
if(v->expr_type != A1TC_UNIVERVAL)
continue;
if(v->value->value.v_integer < LEFTMIN
|| v->value->value.v_integer > RIGHTMAX)
return FL_NOTFIT;
}
if(!expr->combined_constraints)
return (arg->flags & A1C_USE_NATIVE_TYPES)
? FL_FORCED : FL_NOTFIT;
/*
* Second, if -fbless-SIZE is given, the (SIZE()) constraint may be
* applied (non-standard! but we can deal with this) to the type.
* Check the range.
*/
range = asn1constraint_compute_PER_range(expr->expr_type,
expr->combined_constraints, ACT_CT_SIZE, 0, 0,
CPR_simulate_fbless_SIZE);
if(range) {
if(!range->incompatible) {
right = range->right;
/* Use 4 instead of sizeof(long) is justified! */
if(right.type == ARE_VALUE && right.value <= 4)
return FL_FITSOK;
}
asn1constraint_range_free(range);
}
/*
* Third, pull up the PER visible range of the INTEGER.
*/
range = asn1constraint_compute_PER_range(expr->expr_type,
expr->combined_constraints, ACT_EL_RANGE, 0, 0, 0);
if(!range
|| range->empty_constraint
|| range->extensible
|| range->incompatible
|| range->not_PER_visible
) {
asn1constraint_range_free(range);
return (arg->flags & A1C_USE_NATIVE_TYPES)
? FL_FORCED : FL_NOTFIT;
}
left = range->left;
right = range->right;
asn1constraint_range_free(range);
/* If some fixed value is outside of target range, not fit */
if(left.type == ARE_VALUE
&& (left.value < LEFTMIN || left.value > RIGHTMAX))
return FL_NOTFIT;
if(right.type == ARE_VALUE
&& (right.value > RIGHTMAX || right.value < LEFTMIN))
return FL_NOTFIT;
/* If the range is open, fits only if -fnative-types is given */
if(left.type != ARE_VALUE || right.type != ARE_VALUE) {
return (arg->flags & A1C_USE_NATIVE_TYPES)
? FL_FORCED : FL_NOTFIT;
}
return FL_FITSOK;
}
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