#include "asn1c_internal.h"
#include "asn1c_constraint.h"
#include "asn1c_misc.h"
#include "asn1c_out.h"
#include <asn1fix_crange.h> /* constraint groker from libasn1fix */
#include <asn1fix_export.h> /* other exportables from libasn1fix */
static int asn1c_emit_constraint_tables(arg_t *arg, int got_size);
static int emit_alphabet_check_loop(arg_t *arg, asn1cnst_range_t *range);
static int emit_value_determination_code(arg_t *arg, asn1p_expr_type_e etype, asn1cnst_range_t *r_value);
static int emit_size_determination_code(arg_t *arg, asn1p_expr_type_e etype);
static asn1p_expr_type_e _find_terminal_type(arg_t *arg);
static int emit_range_comparison_code(arg_t *arg, asn1cnst_range_t *range, const char *varname, asn1c_integer_t natural_start, asn1c_integer_t natural_stop);
static int native_long_sign(asn1cnst_range_t *r); /* -1, 0, 1 */
static int
ulong_optimization(asn1p_expr_type_e etype, asn1cnst_range_t *r_size,
asn1cnst_range_t *r_value)
{
return (!r_size && r_value
&& (etype == ASN_BASIC_INTEGER
|| etype == ASN_BASIC_ENUMERATED)
&& native_long_sign(r_value) == 0);
}
int
asn1c_emit_constraint_checking_code(arg_t *arg) {
asn1cnst_range_t *r_size;
asn1cnst_range_t *r_value;
asn1p_expr_t *expr = arg->expr;
asn1p_expr_type_e etype;
asn1p_constraint_t *ct;
int got_something = 0;
int alphabet_table_compiled;
int produce_st = 0;
int ulong_optimize = 0;
ct = expr->combined_constraints;
if(ct == NULL)
return 1; /* No additional constraints defined */
etype = _find_terminal_type(arg);
r_value=asn1constraint_compute_PER_range(etype, ct, ACT_EL_RANGE,0,0,0);
r_size =asn1constraint_compute_PER_range(etype, ct, ACT_CT_SIZE, 0,0,0);
if(r_value) {
if(r_value->incompatible
|| r_value->empty_constraint
|| (r_value->left.type == ARE_MIN
&& r_value->right.type == ARE_MAX)
|| (etype == ASN_BASIC_BOOLEAN
&& r_value->left.value == 0
&& r_value->right.value == 1)
) {
asn1constraint_range_free(r_value);
r_value = 0;
}
}
if(r_size) {
if(r_size->incompatible
|| r_size->empty_constraint
|| (r_size->left.value == 0 /* or .type == MIN */
&& r_size->right.type == ARE_MAX)
) {
asn1constraint_range_free(r_size);
r_size = 0;
}
}
/*
* Do we really need an "*st = sptr" pointer?
*/
switch(etype) {
case ASN_BASIC_INTEGER:
case ASN_BASIC_ENUMERATED:
if(asn1c_type_fits_long(arg, arg->expr) == FL_NOTFIT)
produce_st = 1;
break;
case ASN_BASIC_REAL:
if((arg->flags & A1C_USE_WIDE_TYPES))
produce_st = 1;
break;
case ASN_BASIC_BIT_STRING:
case ASN_BASIC_OCTET_STRING:
produce_st = 1;
break;
default:
if(etype & ASN_STRING_MASK)
produce_st = 1;
break;
}
if(produce_st) {
char *tname = asn1c_type_name(arg, arg->expr, TNF_SAFE);
OUT("const %s_t *st = (const %s_t *)sptr;\n", tname, tname);
}
if(r_size || r_value) {
if(r_size) {
OUT("size_t size;\n");
}
if(r_value)
switch(etype) {
case ASN_BASIC_INTEGER:
case ASN_BASIC_ENUMERATED:
if(native_long_sign(r_value) >= 0) {
ulong_optimize = ulong_optimization(etype, r_size, r_value);
if(!ulong_optimize) {
OUT("unsigned long value;\n");
}
} else {
OUT("long value;\n");
}
break;
case ASN_BASIC_REAL:
OUT("double value;\n");
break;
case ASN_BASIC_BOOLEAN:
OUT("BOOLEAN_t value;\n");
break;
default:
break;
}
}
OUT("\n");
/*
* Protection against null input.
*/
OUT("if(!sptr) {\n");
INDENT(+1);
OUT("_ASN_CTFAIL(app_key, td, sptr,\n");
OUT("\t\"%%s: value not given (%%s:%%d)\",\n");
OUT("\ttd->name, __FILE__, __LINE__);\n");
OUT("return -1;\n");
INDENT(-1);
OUT("}\n");
OUT("\n");
if((r_value) && (!ulong_optimize))
emit_value_determination_code(arg, etype, r_value);
if(r_size)
emit_size_determination_code(arg, etype);
INDENT(-1);
REDIR(OT_CTABLES);
/* Emit FROM() tables */
alphabet_table_compiled =
(asn1c_emit_constraint_tables(arg, r_size?1:0) == 1);
REDIR(OT_CODE);
INDENT(+1);
/*
* Optimization for unsigned longs.
*/
if(ulong_optimize) {
OUT("\n");
OUT("/* Constraint check succeeded */\n");
OUT("return 0;\n");
return 0;
}
/*
* Here is an if() {} else {} consrtaint checking code.
*/
OUT("\n");
OUT("if(");
INDENT(+1);
if(r_size) {
if(got_something++) { OUT("\n"); OUT(" && "); }
OUT("(");
emit_range_comparison_code(arg, r_size, "size", 0, -1);
OUT(")");
}
if(r_value) {
if(got_something++) { OUT("\n"); OUT(" && "); }
OUT("(");
if(etype == ASN_BASIC_BOOLEAN)
emit_range_comparison_code(arg, r_value,
"value", 0, 1);
else
emit_range_comparison_code(arg, r_value,
"value", -1, -1);
OUT(")");
}
if(alphabet_table_compiled) {
if(got_something++) { OUT("\n"); OUT(" && "); }
OUT("!check_permitted_alphabet_%d(%s)",
arg->expr->_type_unique_index,
produce_st ? "st" : "sptr");
}
if(!got_something) {
OUT("1 /* No applicable constraints whatsoever */");
OUT(") {\n");
INDENT(-1);
INDENTED(OUT("/* Nothing is here. See below */\n"));
OUT("}\n");
OUT("\n");
return 1;
}
INDENT(-1);
OUT(") {\n");
INDENT(+1);
switch(etype) {
case ASN_CONSTR_SEQUENCE_OF:
case ASN_CONSTR_SET_OF:
OUT("/* Perform validation of the inner elements */\n");
OUT("return td->check_constraints(td, sptr, ctfailcb, app_key);\n");
break;
default:
OUT("/* Constraint check succeeded */\n");
OUT("return 0;\n");
}
INDENT(-1);
OUT("} else {\n");
INDENT(+1);
OUT("_ASN_CTFAIL(app_key, td, sptr,\n");
OUT("\t\"%%s: constraint failed (%%s:%%d)\",\n");
OUT("\ttd->name, __FILE__, __LINE__);\n");
OUT("return -1;\n");
INDENT(-1);
OUT("}\n");
return 0;
}
static int
asn1c_emit_constraint_tables(arg_t *arg, int got_size) {
asn1c_integer_t range_start;
asn1c_integer_t range_stop;
asn1p_expr_type_e etype;
asn1cnst_range_t *range;
asn1p_constraint_t *ct;
int utf8_full_alphabet_check = 0;
int max_table_size = 256;
int table[256];
int use_table;
ct = arg->expr->combined_constraints;
if(!ct) return 0;
etype = _find_terminal_type(arg);
range = asn1constraint_compute_PER_range(etype, ct, ACT_CT_FROM, 0,0,0);
if(!range) return 0;
if(range->incompatible
|| range->empty_constraint) {
asn1constraint_range_free(range);
return 0;
}
if(range->left.type == ARE_MIN
&& range->right.type == ARE_MAX) {
/*
* The permitted alphabet constraint checker code guarantees
* that either both bounds (left/right) are present, or
* they're absent simultaneously. Thus, this assertion
* legitimately holds true.
*/
assert(range->el_count == 0);
/* The full range is specified. Ignore it. */
return 0;
}
range_start = range->left.value;
range_stop = range->right.value;
assert(range->left.type == ARE_VALUE);
assert(range->right.type == ARE_VALUE);
assert(range_start <= range_stop);
range_start = 0; /* Force old behavior */
/*
* Check if we need a test table to check the alphabet.
*/
use_table = 1;
if(range->el_count == 0) {
/*
* It's better to have a short if() check
* than waste 1k of table space
*/
use_table = 0;
}
if((range_stop - range_start) > 255)
use_table = 0;
if(etype == ASN_STRING_UTF8String) {
if(range_stop >= 0x80)
use_table = 0;
else
max_table_size = 128;
}
if(use_table) {
int cardinal = 0;
int i, n = 0;
int untl;
memset(table, 0, sizeof(table));
for(i = -1; i < range->el_count; i++) {
asn1cnst_range_t *r;
asn1c_integer_t v;
if(i == -1) {
if(range->el_count) continue;
r = range;
} else {
r = range->elements[i];
}
for(v = r->left.value; v <= r->right.value; v++) {
assert((v - range_start) >= 0);
assert((v - range_start) < max_table_size);
table[v - range_start] = ++n;
}
}
untl = (range_stop - range_start) + 1;
untl += (untl % 16)?16 - (untl % 16):0;
OUT("static const int permitted_alphabet_table_%d[%d] = {\n",
arg->expr->_type_unique_index, max_table_size);
for(n = 0; n < untl; n++) {
cardinal += table[n] ? 1 : 0;
OUT("%2d,", table[n]);
if(!((n+1) % 16)) {
int c;
if(!n || (n-15) + range_start >= 0x80) {
OUT("\n");
continue;
}
OUT("\t/* ");
for(c = n - 15; c <= n; c++) {
if(table[c]) {
int a = c + range_start;
if(a > 0x20 && a < 0x80)
OUT("%c", a);
else
OUT(".");
} else {
OUT(" ");
}
}
OUT(" */");
OUT("\n");
}
}
OUT("};\n");
if((arg->flags & A1C_GEN_PER)
&& (etype & ASN_STRING_KM_MASK)) {
int c;
OUT("static const int permitted_alphabet_code2value_%d[%d] = {\n",
arg->expr->_type_unique_index, cardinal);
for(n = c = 0; c < max_table_size; c++) {
if(table[c]) {
OUT("%d,", c);
if(!((++n) % 16)) OUT("\n");
}
}
OUT("};\n");
OUT("\n");
DEBUG("code2value map gen for %s", arg->expr->Identifier);
arg->expr->_mark |= TM_PERFROMCT;
}
OUT("\n");
} else if(etype == ASN_STRING_UTF8String) {
/*
* UTF8String type is a special case in many respects.
*/
if(got_size) {
/*
* Size has been already determined.
* The UTF8String length checker also checks
* for the syntax validity, so we don't have
* to repeat this process twice.
*/
asn1constraint_range_free(range);
return 0;
} else {
utf8_full_alphabet_check = 1;
}
} else {
/*
* This permitted alphabet check will be
* expressed using conditional statements
* instead of table lookups. Table would be
* to large or otherwise inappropriate (too sparse?).
*/
}
OUT("static int check_permitted_alphabet_%d(const void *sptr) {\n",
arg->expr->_type_unique_index);
INDENT(+1);
if(utf8_full_alphabet_check) {
OUT("if(UTF8String_length((const UTF8String_t *)sptr) < 0)\n");
OUT("\treturn -1; /* Alphabet (sic!) test failed. */\n");
OUT("\n");
} else {
if(use_table) {
OUT("const int *table = permitted_alphabet_table_%d;\n",
arg->expr->_type_unique_index);
emit_alphabet_check_loop(arg, 0);
} else {
emit_alphabet_check_loop(arg, range);
}
}
OUT("return 0;\n");
INDENT(-1);
OUT("}\n");
OUT("\n");
asn1constraint_range_free(range);
return 1;
}
static int
emit_alphabet_check_loop(arg_t *arg, asn1cnst_range_t *range) {
asn1c_integer_t natural_stop;
asn1p_expr_t *terminal;
char *tname;
terminal = asn1f_find_terminal_type_ex(arg->asn, arg->expr);
if(terminal) {
OUT("/* The underlying type is %s */\n",
ASN_EXPR_TYPE2STR(terminal->expr_type));
} else {
terminal = arg->expr;
}
tname = asn1c_type_name(arg, terminal, TNF_SAFE);
OUT("const %s_t *st = (const %s_t *)sptr;\n", tname, tname);
switch(terminal->expr_type) {
case ASN_STRING_UTF8String:
OUT("const uint8_t *ch = st->buf;\n");
OUT("const uint8_t *end = ch + st->size;\n");
OUT("\n");
OUT("for(; ch < end; ch++) {\n");
INDENT(+1);
OUT("uint8_t cv = *ch;\n");
if(!range) OUT("if(cv >= 0x80) return -1;\n");
natural_stop = 0xffffffffUL;
break;
case ASN_STRING_UniversalString:
OUT("const uint8_t *ch = st->buf;\n");
OUT("const uint8_t *end = ch + st->size;\n");
OUT("\n");
OUT("if(st->size %% 4) return -1; /* (size%%4)! */\n");
OUT("for(; ch < end; ch += 4) {\n");
INDENT(+1);
OUT("uint32_t cv = (ch[0] << 24)\n");
OUT("\t\t| (ch[1] << 16)\n");
OUT("\t\t| (ch[2] << 8)\n");
OUT("\t\t| ch[3];\n");
if(!range) OUT("if(cv > 255) return -1;\n");
natural_stop = 0xffffffffUL;
break;
case ASN_STRING_BMPString:
OUT("const uint8_t *ch = st->buf;\n");
OUT("const uint8_t *end = ch + st->size;\n");
OUT("\n");
OUT("if(st->size %% 2) return -1; /* (size%%2)! */\n");
OUT("for(; ch < end; ch += 2) {\n");
INDENT(+1);
OUT("uint16_t cv = (ch[0] << 8)\n");
OUT("\t\t| ch[1];\n");
if(!range) OUT("if(cv > 255) return -1;\n");
natural_stop = 0xffff;
break;
case ASN_BASIC_OCTET_STRING:
default:
OUT("const uint8_t *ch = st->buf;\n");
OUT("const uint8_t *end = ch + st->size;\n");
OUT("\n");
OUT("for(; ch < end; ch++) {\n");
INDENT(+1);
OUT("uint8_t cv = *ch;\n");
natural_stop = 0xff;
break;
}
if(range) {
OUT("if(!(");
emit_range_comparison_code(arg, range, "cv", 0, natural_stop);
OUT(")) return -1;\n");
} else {
OUT("if(!table[cv]) return -1;\n");
}
INDENT(-1);
OUT("}\n");
return 0;
}
static int
emit_range_comparison_code(arg_t *arg, asn1cnst_range_t *range, const char *varname, asn1c_integer_t natural_start, asn1c_integer_t natural_stop) {
int ignore_left;
int ignore_right;
int generated_something = 0;
int i;
for(i = -1; i < range->el_count; i++) {
asn1cnst_range_t *r;
if(i == -1) {
if(range->el_count) continue;
r = range;
} else {
if(i) OUT(" || ");
r = range->elements[i];
}
if(r != range) OUT("(");
ignore_left = (r->left.type == ARE_MIN)
|| (natural_start != -1
&& r->left.value <= natural_start);
ignore_right = (r->right.type == ARE_MAX)
|| (natural_stop != -1
&& r->right.value >= natural_stop);
if(ignore_left && ignore_right) {
OUT("1 /* Constraint matches natural range of %s */",
varname);
continue;
}
if(ignore_left) {
OUT("%s <= ", varname);
OINT(r->right.value);
} else if(ignore_right) {
OUT("%s >= ", varname);
OINT(r->left.value);
} else if(r->left.value == r->right.value) {
OUT("%s == ", varname);
OINT(r->right.value);
} else {
OUT("%s >= ", varname);
OINT(r->left.value);
OUT(" && ");
OUT("%s <= ", varname);
OINT(r->right.value);
}
if(r != range) OUT(")");
generated_something = 1;
}
return generated_something;
}
static int
emit_size_determination_code(arg_t *arg, asn1p_expr_type_e etype) {
switch(etype) {
case ASN_BASIC_BIT_STRING:
OUT("if(st->size > 0) {\n");
OUT("\t/* Size in bits */\n");
OUT("\tsize = 8 * st->size - (st->bits_unused & 0x07);\n");
OUT("} else {\n");
OUT("\tsize = 0;\n");
OUT("}\n");
break;
case ASN_STRING_UniversalString:
OUT("size = st->size >> 2;\t/* 4 byte per character */\n");
break;
case ASN_STRING_BMPString:
OUT("size = st->size >> 1;\t/* 2 byte per character */\n");
break;
case ASN_STRING_UTF8String:
OUT("size = UTF8String_length(st);\n");
OUT("if((ssize_t)size < 0) {\n");
OUT("\t_ASN_CTFAIL(app_key, td, sptr,\n");
OUT("\t\t\"%%s: UTF-8: broken encoding (%%s:%%d)\",\n");
OUT("\t\ttd->name, __FILE__, __LINE__);\n");
OUT("\treturn -1;\n");
OUT("}\n");
break;
case ASN_CONSTR_SET_OF:
case ASN_CONSTR_SEQUENCE_OF:
OUT("/* Determine the number of elements */\n");
OUT("size = _A_C%s_FROM_VOID(sptr)->count;\n",
etype==ASN_CONSTR_SET_OF?"SET":"SEQUENCE");
break;
case ASN_BASIC_OCTET_STRING:
OUT("size = st->size;\n");
break;
default:
if(etype & ASN_STRING_MASK) {
OUT("size = st->size;\n");
break;
} else {
const char *type_name = ASN_EXPR_TYPE2STR(etype);
if(!type_name) type_name = arg->expr->Identifier;
WARNING("SizeConstraint is not defined for %s",
type_name);
OUT_NOINDENT("#warning SizeConstraint "
"is not defined for %s!\n", type_name);
OUT("size = st->size;\n");
}
return -1;
}
return 0;
}
static int
emit_value_determination_code(arg_t *arg, asn1p_expr_type_e etype, asn1cnst_range_t *r_value) {
switch(etype) {
case ASN_BASIC_INTEGER:
case ASN_BASIC_ENUMERATED:
if(asn1c_type_fits_long(arg, arg->expr) == FL_FITS_UNSIGN) {
OUT("value = *(const unsigned long *)sptr;\n");
} else if(asn1c_type_fits_long(arg, arg->expr) != FL_NOTFIT) {
OUT("value = *(const long *)sptr;\n");
} else {
/*
* In some cases we can explore our knowledge of
* underlying INTEGER_t->buf format.
*/
if(r_value->el_count == 0
&& (
/* Speed-up common case: (0..MAX) */
(r_value->left.type == ARE_VALUE
&& r_value->left.value == 0
&& r_value->right.type == ARE_MAX)
||
/* Speed-up common case: (MIN..-1) */
(r_value->left.type == ARE_MIN
&& r_value->right.type == ARE_VALUE
&& r_value->right.value == -1)
)) {
OUT("/* Check if the sign bit is present */\n");
OUT("value = st->buf ? ((st->buf[0] & 0x80) ? -1 : 1) : 0;\n");
break;
}
if(native_long_sign(r_value) >= 0) {
/* Special case for treating unsigned longs */
OUT("if(asn_INTEGER2ulong(st, &value)) {\n");
INDENT(+1);
OUT("_ASN_CTFAIL(app_key, td, sptr,\n");
OUT("\t\"%%s: value too large (%%s:%%d)\",\n");
OUT("\ttd->name, __FILE__, __LINE__);\n");
OUT("return -1;\n");
INDENT(-1);
OUT("}\n");
} else {
OUT("if(asn_INTEGER2long(st, &value)) {\n");
INDENT(+1);
OUT("_ASN_CTFAIL(app_key, td, sptr,\n");
OUT("\t\"%%s: value too large (%%s:%%d)\",\n");
OUT("\ttd->name, __FILE__, __LINE__);\n");
OUT("return -1;\n");
INDENT(-1);
OUT("}\n");
}
}
break;
case ASN_BASIC_REAL:
if(arg->flags & A1C_USE_WIDE_TYPES) {
OUT("if(asn_REAL2double(st, &value)) {\n");
INDENT(+1);
OUT("_ASN_CTFAIL(app_key, td, sptr,\n");
OUT("\t\"%%s: value too large (%%s:%%d)\",\n");
OUT("\ttd->name, __FILE__, __LINE__);\n");
OUT("return -1;\n");
INDENT(-1);
OUT("}\n");
} else {
OUT("value = *(const double *)sptr;\n");
}
break;
case ASN_BASIC_BOOLEAN:
OUT("value = (*(const long *)sptr) ? 1 : 0;\n");
break;
default:
WARNING("%s:%d: Value cannot be determined "
"for constraint check for %s",
arg->expr->module->source_file_name,
arg->expr->_lineno,
arg->expr->Identifier
);
OUT_NOINDENT(
"#error %s:%d: Value of %s cannot be determined\n",
arg->expr->module->source_file_name,
arg->expr->_lineno,
arg->expr->Identifier
);
break;
}
return 0;
}
static asn1p_expr_type_e
_find_terminal_type(arg_t *arg) {
asn1p_expr_t *expr;
expr = asn1f_find_terminal_type_ex(arg->asn, arg->expr);
if(expr) return expr->expr_type;
return A1TC_INVALID;
}
static int
native_long_sign(asn1cnst_range_t *r) {
if(r->left.type == ARE_VALUE
&& r->left.value >= 0
&& r->right.type == ARE_VALUE
&& r->right.value > 2147483647
&& r->right.value <= 4294967295UL) {
if(r->el_count == 0
&& r->left.value == 0
&& r->right.value == 4294967295UL)
return 0;
else
return 1;
} else {
return -1;
}
}