campo-sirio/include/dongle.cpp

#include <xvt.h>

#include <applicat.h>
#include <config.h>
#include <dongle.h>
#include <isamrpc.h>
#include <utility.h>

///////////////////////////////////////////////////////////
// Dongle stuff
///////////////////////////////////////////////////////////

#ifndef _DEMO_

#define USERADR    26952
#define AGAADR     26953
#define PRASSIADR  26954
#define REFKEY (unsigned char*)"CAMPOKEY"
#define VERKEY (unsigned char*)"<22>pو<70>c<EFBFBD><"

#pragma pack(push, 1)

struct TEutronHeader
{ 
  char           _serno[8];             //  8
  unsigned short _year_assist;          // 10
  unsigned short _max_users;            // 12
  unsigned long  _last_date;            // 16
  unsigned long  _scad_date;            // 20
  unsigned long  _checksum;             // 24 
  unsigned short _version;              // 26
  unsigned short _patch;                // 28
  unsigned short _offset_to_bits;       // 30
  unsigned short _size_of_bits;         // 32
};

struct TEutronFooter
{                
  unsigned long _size;                  // Should be sizeof(TEutronFooter)
  unsigned long _checksum;              // Much smarter position than header
  unsigned long _filler1;
  unsigned long _filler2;
  unsigned long _filler3;
  unsigned long _filler4;
  unsigned long _filler5;
  unsigned long _last_assist;                   // Last date of assistance query
  unsigned long _assistance[MAX_DONGLE_ASSIST]; // Pre-payed assistance
  
  unsigned long checksum(bool set);
  bool valid();
  TEutronFooter();
};

#pragma pack(pop)

TEutronFooter::TEutronFooter()
{
  const int s = sizeof(TEutronFooter);
  memset(&_size, 0, s);
  _size = s;
}

unsigned long TEutronFooter::checksum(bool set)
{
  if (set) _size = sizeof(TEutronFooter);

  const word offset = sizeof(_size) + sizeof(_checksum);
  byte* ptr = (byte*)(&_size) + offset;
  const word len = word(_size - offset);
  
  unsigned long cs = 0;
  for (word i = 0; i < len; i++, ptr++)
    cs += *ptr | ~(short(*ptr << 8));
  if (set) _checksum = cs;
  return cs;  
}

bool TEutronFooter::valid() 
{
  if (_size == 0 || _checksum == 0)
    return FALSE;
  return _checksum == checksum(FALSE);
}

#endif // _DEMO_

///////////////////////////////////////////////////////////
// Current dongle
///////////////////////////////////////////////////////////

static TDongle* _dongle = NULL;

TDongle& dongle() 
{ 
  if (_dongle == NULL)
    _dongle = new TDongle;
  return *_dongle; 
}

bool destroy_dongle()
{
  bool ok = _dongle != NULL;
  if (ok)
  {
    delete _dongle;
    _dongle = NULL;  
  }
  return ok;
}

///////////////////////////////////////////////////////////
// Bit helper functions
///////////////////////////////////////////////////////////

inline bool test_bit(word w, int b)
{                            
  bool on = (w & (1 << b)) != 0;
  return on;
}

inline void set_bit(word& w, int b, bool on = TRUE)
{                        
  if (on)  
    w |= 1 << b;
  else  
    w &= ~(1 << b);
}

inline void reset_bit(word& w, byte b)
{                        
  w &= ~(1 << b);
}

///////////////////////////////////////////////////////////
// TDongle
///////////////////////////////////////////////////////////

TDongle::TDongle() 
       : _hardware(_dongle_unknown), _type(_no_dongle), _serno(0xFFFF), 
         _dirty(FALSE), _max_users(1), _year_assist(1997)
{
  memset(_eprom, 0, sizeof(_eprom));
  memset(_assist, 0, sizeof(_assist));
}  

TDongle::~TDongle() 
{ 
  if (_serno != 0xFFFF)
    logout(); 
}

const TString& TDongle::administrator(TString* pwd)
{
  if (_admin.empty())
  {
    TConfig ini("install.ini", "Main");
    _admin = ini.get("Administrator");
    if (_admin.empty())
      _admin = "ADMIN";
    else
      _admin = ::decode(_admin);
    _admpwd = ini.get("Password");
    if (_admpwd.empty())
		{
      _admpwd = _admin;
			_admpwd.lower();
			_admpwd.insert(".", 2);
		}
    else
      _admpwd = ::decode(_admpwd);
  }
  if (pwd)
    *pwd = _admpwd;
  return _admin;
}


// Data punta ad un array di 4 words 
// Deve essere cosi' per problemi del C,
// non trasformare in array: pena di morte! 
void TDongle::garble(word* data) const
{   
#ifndef _DEMO_
  switch (_hardware)
  {
  case _dongle_hardlock:
    xvt_dongle_hl_crypt(data);
    break;
  case _dongle_eutron:
    xvt_dongle_sl_crypt(data);
    break;
  default:
    break;  
  }  
#endif
}

bool TDongle::already_programmed() const
{     
#ifndef _DEMO_
  if (_hardware == _dongle_hardlock)
  {
    word data[4];
    memcpy(data, &_eprom[60], sizeof(data));
    garble(data);
    
    if (data[0] < 1997 || data[0] > 2997)
      return FALSE;
      
    if (data[1] == 0 || data[1] >= 10000)  
      return FALSE;
    
    const TDate today(TODAY);
    const long& giulio = (const long&)data[2];
    const long yyyymmdd = today.julian2date(giulio);
    const TDate d(yyyymmdd);
    if (d.year() < 1997 || d > today)
      return FALSE;
  } else
  if (_hardware == _dongle_eutron)
  {
    const TEutronHeader* eh = (const TEutronHeader*)_eprom;
    if (eh->_serno[0] == 0 || eh->_checksum == 0)
      return FALSE;   // Really virgin.
      
    unsigned long cs = 0;
    for (byte* ptr = (byte*)_eprom; ptr < (byte*)&eh->_checksum; ptr++)
      cs += *ptr | ~(short(*ptr << 8));
    if (eh->_checksum != cs)  
      return FALSE;   // Malicious programming!
  }   
#endif // _DEMO_    
  return TRUE;  
}
           
#ifndef _DEMO_

bool TDongle::hardlock_login(bool test_all_keys)
{
  bool ok = TRUE;
  _type = _user_dongle;
  if (test_all_keys)
  {
    xvt_dongle_hl_logout();
    if (xvt_dongle_hl_login(AGAADR, REFKEY, VERKEY)) 
      _type = _aga_dongle;
    else
    {
      xvt_dongle_hl_logout();
      if (xvt_dongle_hl_login(PRASSIADR, REFKEY, VERKEY))
        _type = _prassi_dongle;
    }
  }  
  xvt_dongle_hl_logout();
  ok = xvt_dongle_hl_login(USERADR, REFKEY, VERKEY) != 0;
  
  if (ok)
  {     
    _hardware = _dongle_hardlock;
    
    xvt_dongle_hl_read_block((unsigned char*)_eprom);

    word data[4];
    memcpy(data, _eprom, sizeof(data));
    garble(data);
    
    if (data[0] == 0xFAE8)
      _serno = data[1];
    else
    {                  
      if (data[0] == 0x3283 || data[0] == 0xA3AA) // chiave programmatori !!
      {         
        if (_type == _user_dongle)
          _type = _developer_dongle;
        _serno = 0;  
      }  
    }  
  }  

  if (ok) 
  {
    _max_users = 1;
    _last_update = TDate(TODAY);
    _year_assist = _last_update.year();

    if (_type == _user_dongle)
    {  
      const bool already = already_programmed();
      
      _module.reset(); // Disattiva  tutti i moduli
      const int last_word = already ? 12 : 4;                    
      word data[4];

      // Legge flag di attivazione dei moduli
      for (int i = 0; i < last_word; i += 4)
      {
        memcpy(data, &_eprom[48+i], sizeof(data));
        garble(data);
        if (data[3] == _serno) // Validate block
        {
          for (int j = 0; j < 3; j++)
          {
            word parola = data[j] ^ _serno;
            if (parola)
            {
              for (int b = 15; b >= 0; b--)
              {
                if (test_bit(parola, b))             
                {
                  const word bit = i * 12 + j * 16 + b;
                  _module.set(bit+1);
                }  
              }  
            }  
          }
        }
        else
          break;
      }
      _module.set(0, TRUE); // Forza l'attivazione della base

      // Legge anno di assitenza e numero massimo di utenti
      memcpy(data, &_eprom[60], sizeof(data));
      garble(data);      
      
      if (already)
      {
        _year_assist = data[0];
        _max_users = data[1];
        const long& giulio = (const long&)data[2];
        const long yyyymmdd = _last_update.julian2date(giulio);
        _last_update = yyyymmdd;
      }
      else
      {
        _year_assist = 0;
        _dirty = TRUE;
      }
    }  
    else
    {                   
      _module.set(255); // Last module on key
      _module.set();     // Activate all modules

      _max_users = 1;
      _last_update = TDate(TODAY);
      _year_assist = _last_update.year();
    }  
  }  
  else
    _type = _no_dongle;
  
  return ok;  
}

bool TDongle::eutron_login(bool test_all_keys)
{
  bool ok = FALSE;

  const char* labels[4] = { "AGA.INFORMATICA", "AGA.PRASSI", 
                            "AGA.CAMPO", "25EBAI" };
  TDongleType types[4]  = { _aga_dongle, _prassi_dongle, 
                            _user_dongle, _developer_dongle };
  for (int k = test_all_keys ? 0 : 2; k < 4; k++)
  {
    const unsigned char* pwd = (const unsigned char*)::encode(labels[k]);
    ok = xvt_dongle_sl_login((const unsigned char*)labels[k], pwd) != 0;
    if (ok)
    {                  
      _hardware = _dongle_eutron;
      _type = types[k];
      break;
    }
  }  
  if (ok)
  { 
    _serno = 0;
    _max_users = 1;
    _last_update = TDate(TODAY);
    _year_assist = _last_update.year();

    if (_type == _user_dongle)
    {   
      _module.reset();   // Disattiva tutti i moduli
      if (read_words(0, sizeof(TEutronHeader) / 2, _eprom))
      {
        const TEutronHeader* eh = (const TEutronHeader*)_eprom;
        TString16 serno; serno.strncpy(eh->_serno, 8);
        _serno = unsigned(atol(serno));
        if (already_programmed())
        {
          _max_users   = eh->_max_users;
          _last_update = eh->_last_date;
          _year_assist = eh->_year_assist;
          
          // Calcola il numero della word dove cominciano i bit di attivazione
          unsigned short otb = eh->_offset_to_bits;
          if (otb == 0) otb = 16;   // Compatibile Hardlock

          unsigned short sob = eh->_size_of_bits;
          if (sob == 0) sob = 16;   // Compatibile Hardlock
          
          word data[64];
          if (read_words(otb, sob, data))
          {  
            int module = 1;
            for (word w = 0; w < sob; w++)
            {
              for (int b = 0; b < 16; b++)
              {
                if (test_bit(data[w], b))
                  _module.set(module);
                module++;  
              }    
            }
          }
          
          memset(_assist, 0, sizeof(_assist));  // Azzera pre-pagato
          TEutronFooter ef;
          if (read_words(otb+sob, sizeof(ef)/2, (word*)&ef))
          {
            if (ef.valid())
            {    
              _last_assist = ef._last_assist;
              memcpy(_assist, ef._assistance, sizeof(_assist));
            }
          }
        }  
        else
          _dirty = TRUE;
      }  
      _module.set(0, TRUE); // Forza l'attivazione della base
    }
    else
    {
      _module.set(255); // Last module on key
      _module.set();    // Activate all modules
    }  
  }
  return ok;
}

bool TDongle::network_login(bool test_all_keys)
{
  if (network())
    rpc_UserLogout();
      
  TConfig ini(CONFIG_INSTALL, "Server");
  const char* server = ini.get("Dongle");
  const char* guest  = "******";
  const TString16 appname = main_app().name();
  const char* utente = (!main_app().is_running() && appname == "ba0100") ? guest : user();

  const bool ok = rpc_UserLogin(server, utente, "******", appname);
  if (ok)
  {       
    _hardware = _dongle_network;
    _type = _user_dongle;
    _serno = rpc_DongleNumber();
    _max_users = 1;
    _last_update = TDate(TODAY);
    _year_assist = rpc_DongleYear();
    rpc_DongleModules(_module);
  } 
  return ok;
}

#endif  // _DEMO_

int TDongle::can_try_server() const
{
  if (xvt_sys_dongle_server_is_running())
    return 3;

  TConfig ini(CONFIG_INSTALL, "Server");
  const TString& dongle = ini.get("Dongle");
  return dongle.not_empty();
}

bool TDongle::login(bool test_all_keys)
{                                                                   
  bool ok = TRUE;

#ifdef _DEMO_  
  _hardware = _dongle_hardlock;
  _type = _user_dongle;
  _serno = 0;
  _max_users = 1;
  _last_update = TDate(TODAY);
  _year_assist = _last_update.year();
  _module.set(255);  // Last module on key
  _module.set();     // Activate all modules
#else
  if (_type != _no_dongle) // Already logged in
    logout();

  TDongleHardware hw = _hardware;               
  if (hw == _dongle_unknown)
  {                        
		if (can_try_server())
    {
      hw = _dongle_network;
    }
    else
    {
      TConfig ini(CONFIG_INSTALL, "Main");
      hw = (TDongleHardware)ini.get_int("Donglehw");
    }
  }
  switch(hw)
  {
  case _dongle_hardlock: 
    ok = hardlock_login(test_all_keys); 
    break;
  case _dongle_eutron: 
    ok = eutron_login(test_all_keys); 
    break;
  case _dongle_network: 
    ok = network_login(test_all_keys);
    break;
  default:
    ok = FALSE;
    break;
  }
  if (!ok) 
  {
    // retry login for various dongles  ...
    const int use_server = can_try_server();
    if (use_server != 3) // Non sono obbligato ad usare il Dongle Server 
    {
      if (!ok && hw != _dongle_eutron)
        ok = eutron_login(test_all_keys);
      if (!ok && hw != _dongle_hardlock)
        ok = hardlock_login(test_all_keys);
    }
    
		if (ok)
    {
      TConfig ini(CONFIG_INSTALL, "Main");
      ini.set("Donglehw",(int)_hardware);
    }
  }
#endif  
  return ok;
}

bool TDongle::logout()
{ 
#ifndef _DEMO_
  if (_type != _no_dongle)
  {
    switch (_hardware)
    {
    case _dongle_hardlock:  
      xvt_dongle_hl_logout(); 
      break;
    case _dongle_eutron:   
      xvt_dongle_sl_logout(); 
      break;
    case _dongle_network:
      rpc_UserLogout();
      break;
    default:
      break;  
    }
  }  
#endif  

  _type = _no_dongle;
  _serno = 0xFFFF;

  return TRUE;
}

// Data punta ad un array di 4 words 
// Deve essere cosi' per problemi del C,
// non trasformare in array: pena di morte! 
bool TDongle::read_words(word reg, word len, word* ud) const
{         
  bool ok = FALSE;
#ifndef _DEMO_ 
  switch (_hardware)
  { 
  case _dongle_hardlock:
    {
      for (word i = 0; i < len; i++)
        xvt_dongle_hl_read(reg+i, &ud[i]);
      ok = TRUE;
    }  
    break;
  case _dongle_eutron:
    while (len > 0)
    {
      const unsigned short size = (len <= 16) ? len : 16;
      ok = xvt_dongle_sl_read_block(reg, size, ud) != 0;
      if (!ok)
      {
        yesnofatal_box("EUTRON read error");
        break;
      }  
      len -= size;
      reg += size;
      ud  += size;
    }
    break; 
  default:
    break;
  }  
#endif // _DEMO_
  return ok;
}

// Data punta ad un array di 4 words 
// Deve essere cosi' per problemi del C,
// non trasformare in array: pena di morte! 
bool TDongle::write_words(word reg, word len, word* data) const
{                     
  bool ok = FALSE;
#ifndef _DEMO_ 
  switch(_hardware)
  {                
  case _dongle_hardlock:
    {
      for (word r = 0; r < len; r++)
      {           
        const word address = reg+r;
        ok = xvt_dongle_hl_write(address, data[r]) != 0;
      }  
    }  
    break;
  case _dongle_eutron:
    while (len > 0)
    {
      const unsigned short size = (len <= 16) ? len : 16;
      ok = xvt_dongle_sl_write_block(reg, size, data) != 0;
      if (!ok)
        break;
      len -= size;
      reg += size;
      data  += size;
    }
    break;
  default:
    break;  
  }
#endif // _DEMO_
  return ok;
}

#ifndef _DEMO_                                   

bool TDongle::burn_hardlock()
{
  word data[4];

  const TDate today(TODAY);   
  const bool already = already_programmed();
  if (already)  
  {       
    memcpy(data, &_eprom[60], sizeof(data));
    garble(data);                         
    if (data[0] < 1997 || data[0] > 2997)
      return error_box("On Line Assistance error.");
    if (data[1] == 0 || data[1] >= 10000)
      return error_box("Bad users number.");
    const long& val = (const long&)data[2];
    const long yyyymmdd = today.julian2date(val);
    const TDate date(yyyymmdd);
    if (date > today)
      return error_box("Too late sir: key has already expired!");
  }
  
  data[0] = _year_assist;
  data[1] = _max_users;
  long& val = (long&)data[2];
  val = today.date2julian();
  garble(data);
  write_words(60, 4, data);
  _last_update = today;

  // Il primo bit della memoria della chiave corrisponde al modulo uno 
  // non allo zero (che e' la base ed e' sempre attivo)
  word module = 1;
  for (int octect = 0; octect < 3; octect++)  
  {                                       
    for(int parola = 0; parola < 3; parola++)  
    {        
      word& p = data[parola];
      p = 0;
      for (int bit = 0; bit < 16; bit++)
      {          
        if (active(module))
          set_bit(p, bit);
        module++;
      }
      p ^= _serno;
    }
    data[3] = _serno;
    garble(data);
    write_words(48 + 4*octect, 4, data);
  }
  
  return TRUE;
}

bool TDongle::burn_eutron()
{
  TEutronHeader* eh = (TEutronHeader*)_eprom;
  memset(eh, 0, sizeof(TEutronHeader));
  
  _last_update = TDate(TODAY);
  sprintf(eh->_serno, "%lu", (unsigned long)_serno);
  eh->_year_assist = _year_assist;
  eh->_max_users   = _max_users;
  eh->_last_date   = atol(_last_update.string(ANSI));
  eh->_scad_date   = 0;
  
  unsigned long cs = 0;
  for (byte* ptr = (byte*)_eprom; ptr < (byte*)&eh->_checksum; ptr++)
    cs += *ptr | ~(short(*ptr << 8));
  eh->_checksum = cs;
  
  const word otb = sizeof(TEutronHeader) / 2;
  const word sob = 16;
  eh->_offset_to_bits = otb;
  eh->_size_of_bits = sob;
  
  bool ok = write_words(0, otb, _eprom);
  
  if (ok)
  {
    word data[sob]; memset(data, 0, sizeof(data));
    for (int module = 1; module < 256; module++)
    {                             
      if (active(module))
      {
        word& w = data[(module-1) / 16];
        set_bit(w, (module-1) % 16, TRUE);
      }  
    }
    ok = write_words(otb, sob, data);
  }
  
  if (ok)
  {                             
    TEutronFooter ef;
    CHECK(sizeof(ef._assistance) == sizeof(_assist), "Assistance size mismatch");
    ef._last_assist = _last_assist.year()*10000L + _last_assist.month()*100L + _last_assist.day();
    memcpy(ef._assistance, _assist, sizeof(_assist));
    ef.checksum(TRUE);
    ok = write_words(otb+sob, word(ef._size/2), (word*)&ef);
  }
  
  return ok;
}
#endif // _DEMO_

bool TDongle::burn()
{          
  bool ok = local() && _type == _user_dongle;

#ifndef _DEMO_  
  if (ok) 
  {       
    switch(_hardware)
    {
      case _dongle_hardlock: ok = burn_hardlock(); break;
      case _dongle_eutron  : ok = burn_eutron(); break;
      default              : break;
    }  
  }   
#endif    
  if (ok)
    _dirty = FALSE; 

  return ok;  
}

#define BIT31 (1L<<31)
#define MSK31 (~BIT31)

real TDongle::residual_assist(int index, bool lire) const
{
  real imp;
  if (index >= 0 && index < MAX_DONGLE_ASSIST)
  {
    imp = (_assist[index] & MSK31) / 100.0;
    if (lire)
    { imp *= 1936.27; imp.round(-2); }
  }
  return imp; 
}

bool TDongle::can_require_assist(int index) const
{
  bool ok = FALSE;
  if (index >= 0 && index < MAX_DONGLE_ASSIST)
  {                         
    const TDate oggi(TODAY);
    if (oggi == _last_assist)
      ok = (_assist[index] & BIT31) == 0;
    else  
      ok = oggi > _last_assist;
  }
  return ok;
}

bool TDongle::require_assist(int index, real imp, bool lire)
{
  imp *= 100;
  if (lire) { imp /= 1936.27; imp.round(2); }
  
  bool ok = FALSE;
  if (imp > ZERO)
  {
    if (can_require_assist(index))
    {
      const TDate oggi(TODAY);
      if (oggi > _last_assist)
      {
        for (int i = 0; i < MAX_DONGLE_ASSIST; i++)
          _assist[index] &= MSK31;
        _last_assist = oggi;  
      }  
      _assist[index] &= MSK31;
      _assist[index] += imp.integer();
      _assist[index] |= BIT31;
      _dirty = TRUE;
      ok = burn();
    }
  }
  return ok;
}

bool TDongle::pay_assist(int index, real imp, bool lire)
{ 
  bool ok = imp > ZERO;
  if (ok)
  { 
    imp *= 100;
    if (lire) { imp /= 1936.27; imp.round(2); }
  
    unsigned long old_bit31 = _assist[index] & BIT31;
    _assist[index] &= MSK31;
    _assist[index] -= imp.integer();
    _assist[index] |= old_bit31;
    _dirty = TRUE; 
    ok = burn();
  }
  return ok;  
}