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#include <stdio.h>
#include <string.h>
struct Fsm
{
int cs;
// Initialize the machine. Invokes any init statement blocks. Returns 0
// if the machine begins in a non-accepting state and 1 if the machine
// begins in an accepting state.
int init( );
// Execute the machine on a block of data. Returns -1 if after processing
// the data, the machine is in the error state and can never accept, 0 if
// the machine is in a non-accepting state and 1 if the machine is in an
// accepting state.
int execute( const unsigned char *data, int len );
// Indicate that there is no more data. Returns -1 if the machine finishes
// in the error state and does not accept, 0 if the machine finishes
// in any other non-accepting state and 1 if the machine finishes in an
// accepting state.
int finish( );
};
static const char _Fsm_key_offsets [] = { 0, 0, 1, 2, 0 , };
static const unsigned char _Fsm_trans_keys [] = { 232u, 10u, 0u, };
static const char _Fsm_single_lengths [] = { 0, 1, 1, 0, 0 , };
static const char _Fsm_range_lengths [] = { 0, 0, 0, 0, 0 , };
static const char _Fsm_index_offsets [] = { 0, 0, 2, 4, 0 , };
static const char _Fsm_trans_cond_spaces [] = { -1, -1, -1, -1, -1, 0 , };
static const char _Fsm_trans_offsets [] = { 0, 1, 2, 3, 4, 0 , };
static const char _Fsm_trans_lengths [] = { 1, 1, 1, 1, 1, 0 , };
static const char _Fsm_cond_keys [] = { 0, 0, 0, 0, 0, 0 , };
static const char _Fsm_cond_targs [] = { 2, 0, 3, 0, 0, 0 , };
static const char _Fsm_cond_actions [] = { 1, 0, 0, 0, 0, 0 , };
static const char _Fsm_nfa_targs [] = { 0, 0 , };
static const char _Fsm_nfa_offsets [] = { 0, 0, 0, 0, 0 , };
static const char _Fsm_nfa_push_actions [] = { 0, 0 , };
static const char _Fsm_nfa_pop_trans [] = { 0, 0 , };
static const int Fsm_start = 1;
static const int Fsm_first_final = 3;
static const int Fsm_error = 0;
static const int Fsm_en_main = 1;
int Fsm::init( )
{
{
cs = ( int ) Fsm_start;
}
return 0;
}
int Fsm::execute( const unsigned char *_data, int _len )
{
const unsigned char *p = _data;
const unsigned char *pe = _data+_len;
{
int _klen;
const unsigned char *_keys;
const char *_ckeys;
int _cpc;
unsigned int _trans;
unsigned int _cond = 0;
unsigned int _have = 0;
unsigned int _cont = 1;
while ( _cont == 1 )
{
if ( cs == 0 )
_cont = 0;
_have = 0;
if ( p == pe )
{
if ( _have == 0 )
_cont = 0;
}
if ( _cont == 1 )
{
if ( _have == 0 )
{
_keys = _Fsm_trans_keys + _Fsm_key_offsets[cs];
_trans = ( unsigned int ) _Fsm_index_offsets[cs];
_have = 0;
_klen = ( int ) _Fsm_single_lengths[cs];
if ( _klen > 0 )
{
const unsigned char *_lower;
const unsigned char *_mid;
const unsigned char *_upper;
_lower = _keys;
_upper = _keys + _klen - 1;
while ( _upper >= _lower && _have == 0 )
{
_mid = _lower + ((_upper-_lower)>> 1);
if ( ((*( p ))
)< (*( _mid ))
)
_upper = _mid - 1;
else if ( ((*( p ))
)> (*( _mid ))
)
_lower = _mid + 1;
else
{
_trans += ( unsigned int ) (_mid - _keys);
_have = 1;
}
}
if ( _have == 0 )
{
_keys += _klen;
_trans += ( unsigned int ) _klen;
}
}
if ( _have == 0 )
{
_klen = ( int ) _Fsm_range_lengths[cs];
if ( _klen > 0 )
{
const unsigned char *_lower;
const unsigned char *_mid;
const unsigned char *_upper;
_lower = _keys;
_upper = _keys + (_klen<<1)- 2;
while ( _have == 0 && _lower <= _upper )
{
_mid = _lower + (((_upper-_lower)>> 1)& ~1);
if ( ((*( p ))
)< (*( _mid ))
)
_upper = _mid - 2;
else if ( ((*( p ))
)> (*( _mid + 1 ))
)
_lower = _mid + 2;
else
{
_trans += ( unsigned int ) ((_mid - _keys)>>1);
_have = 1;
}
}
if ( _have == 0 )
_trans += ( unsigned int ) _klen;
}
}
_ckeys = _Fsm_cond_keys + _Fsm_trans_offsets[_trans];
_klen = ( int ) _Fsm_trans_lengths[_trans];
_cond = ( unsigned int ) _Fsm_trans_offsets[_trans];
_have = 0;
_cpc = 0;
{
const char *_lower;
const char *_mid;
const char *_upper;
_lower = _ckeys;
_upper = _ckeys + _klen - 1;
while ( _have == 0 && _lower <= _upper )
{
_mid = _lower + ((_upper-_lower)>> 1);
if ( _cpc < ( int ) (*( _mid ))
)
_upper = _mid - 1;
else if ( _cpc > ( int ) (*( _mid ))
)
_lower = _mid + 1;
else
{
_cond += ( unsigned int ) (_mid - _ckeys);
_have = 1;
}
}
if ( _have == 0 )
{
cs = 0;
_cont = 0;
}
}
}
if ( _cont == 1 )
{
cs = ( int ) _Fsm_cond_targs[_cond];
switch ( _Fsm_cond_actions[_cond] ) {
case 1 :
{
printf("yes\n");
}
break;
}
if ( cs == 0 )
_cont = 0;
if ( _cont == 1 )
p += 1;
}
}
}
}
if ( cs == Fsm_error )
return -1;
if ( cs >= Fsm_first_final )
return 1;
return 0;
}
int Fsm::finish()
{
if ( cs == Fsm_error )
return -1;
if ( cs >= Fsm_first_final )
return 1;
return 0;
}
Fsm fsm;
void test( unsigned char *buf, int len )
{
fsm.init();
fsm.execute( buf, len );
if ( fsm.finish() > 0 )
printf("ACCEPT\n");
else
printf("FAIL\n");
}
unsigned char data1[] = { 0xe8, 10 };
unsigned char data2[] = { 0xf8, 10 };
int main()
{
test( data1, 2 );
test( data2, 2 );
return 0;
}
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