source: fact/BIASctrl/User.cc@ 18558

//
// Class processing user input
//

#include "User.h"
#include <readline/readline.h>

using namespace std;

// Branch table for command evaluation
static const struct CL_Struct { const char *Name;    
                                                                void (User::*CommandPointer)();
                                                                unsigned int MinNumParameter;
                                                                bool NeedCrate;
                                                                const char *Parameters;
                                                                const char *Help;
  } CommandList[] = 
   {{"pixel", &User::cmd_hv, 2, true, "<range> <voltage|default|info>", "Change bias of pixels"},
        {"channel", &User::cmd_hv, 2, true, "<range> <voltage|default|info>", "Change bias of channels of active crate"},
    {"gs", &User::cmd_gs, 1, true, "[crate] <volt>", "Global voltage set active crate"},
        {"reset", &User::cmd_reset, 0, true, "", "Reset active crate"},
        {"synch", &User::cmd_synch, 0, true, "", "Synchronize active crate"},
        {"voltage", &User::cmd_status, 0, false, "[dac]", "Show voltage setpoints"},
        {"current", &User::cmd_status, 0, false, "", "Show currents"},
        {"status", &User::cmd_status, 0, false, "[R|I0]", "Show status information"},   
        {"calib", &User::cmd_calib, 1, true, "<V1 V2 Num|invalidate>", "Calibrate current measurement (linear fit between V1 and V2)"},
        {"mode", &User::cmd_mode, 1, true, "<static|dynamic>", "Set voltage stabilization mode (experimental)"},
        {"load", &User::cmd_load, 1, true, "<file>", "Load and set bias settings from file"},
        {"save", &User::cmd_save, 1, true, "<file>", "Save current bias settings to file"},
        {"help", &User::cmd_help, 0, false, "", "Print help"},
        {"exit", &User::cmd_exit, 0, false, "", "Exit program"},
        {".", &User::cmd_shell, 1, false, "<command>", "Execute shell command"}};   

//
// Constructor
//
User::User(string Board): EvidenceServer(SERVER_NAME) {

  vector<string> Text;

  MainThread = pthread_self();

  // DIM console service used in PrintMessage()
  ConsoleText = NULL;
  ConsoleOut = new DimService(SERVER_NAME"/ConsoleOut", (char *) "");

  // Initialize current calibration constants
  R.resize(MAX_NUM_BOARDS*NUM_CHANNELS, numeric_limits<double>::infinity());
  I0.resize(MAX_NUM_BOARDS*NUM_CHANNELS, 0);

  // Get/initialize configuration data
  if (Board.empty()) Board = GetConfig("Boards", "dummy");
  GetConfig("TimeOut");
  GetConfig("VoltageLimit");
  GetConfig("MinResetPeriod");
  GetConfig("RampSpeed");
  GetConfig("UpdatePeriod");

  Text = Tokenize(GetConfig("DefaultVoltage", ""), " \t"); 
  for (unsigned int i=0; i<Text.size(); i++) {
        DefaultVoltage.push_back(atof(Text[i].c_str()));
  }    

  Text = Tokenize(GetConfig("Calibration_R"), " \t"); 
  for (unsigned int i=0; i<Text.size() && i<R.size(); i++) {
        R[i] = atof(Text[i].c_str())/1000.0;
  }

  Text = Tokenize(GetConfig("Calibration_I0"), " \t"); 
  for (unsigned int i=0; i<Text.size() && i<I0.size(); i++) {
        I0[i] = atof(Text[i].c_str());
  }

  // Open device
  Dev = new class Crate(Board, 0, this);

  if (Dev->InitOK) PrintMessage("Synchronized and reset crate %s\n", Board.c_str());
  else {
    Message(WARN, "Failed to synchronize crate %s", Board.c_str());
        delete Dev;
        Dev = NULL;
  }

  // Create PixelMap instance (map from config server)
  DimRpcInfo RPC((char *) "ConfigRequest", (char *) "");
  RPC.setData((char *) "Misc PixelMap");
  PixMap = new PixelMap(std::string(RPC.getString(), RPC.getSize()));
  
  // Install DIM command (after all initialized)
  DIMCommand = new DimCommand((char *) SERVER_NAME"/Command", (char *) "C", this);

  // Create monitor thread and make accessible for sending signal
  if ((pthread_create(&Thread, NULL, (void * (*)(void *)) LaunchMonitor,(void *) this)) != 0) {
    Message(FATAL, "pthread_create() failed with Monitor thread");
  }
}

//
// Destructor
//
User::~User() {

  int Ret;
  
  // Wait for thread to quit (ignore error if thread did already exit)
  if ((Ret = pthread_cancel(Thread)) != 0) {
        if (Ret != ESRCH) Message(ERROR, "pthread_cancel() failed (%s)", strerror(Ret));
  }
  if ((Ret = pthread_join(Thread, NULL)) != 0) Message(ERROR, "pthread_join() failed (%s)", strerror(Ret));

  // Delete crate
  delete Dev;

  delete DIMCommand;    
  delete PixMap;
  delete ConsoleOut;    
  free(ConsoleText);  
}

//
// Process user input
//
void User::commandHandler() {

  // Build string safely
  string Command = string(getCommand()->getString(), getCommand()->getSize());

  // Check if command is legal and ignore empty commands 
  if (getCommand() != DIMCommand || Command.size() < 2) return;

  // Parse command into tokens
  Parameter = Tokenize(Command, " ");

  // Special handling of shell execution
  if (Command[0] == '.') {
    Parameter.clear();
        Parameter.push_back(".");
        Parameter.push_back(Command.substr(1));
  }
  
  // Search for command in command list
  for(unsigned int CmdNumber=0; CmdNumber<sizeof(CommandList)/sizeof(CL_Struct); CmdNumber++) {
    if (Match(Parameter[0], CommandList[CmdNumber].Name)) {
          // Requested command help?
      if (Parameter.size() == 2 && Match(Parameter[1], "?")) {
                PrintMessage("Usage: %s %s\n%s\n", CommandList[CmdNumber].Name, CommandList[CmdNumber].Parameters, CommandList[CmdNumber].Help);
                return;
          }

          // Incorrect number of parameters?
      if (Parameter.size()-1 < CommandList[CmdNumber].MinNumParameter) {
                PrintMessage("Usage: %s %s\n", CommandList[CmdNumber].Name, CommandList[CmdNumber].Parameters);
                return;
          }

          // Check if crate needed
          if (CommandList[CmdNumber].NeedCrate && Dev==NULL) {
                PrintMessage("No crate available\n");
                return;
          }

          // Jump to command function
          (this->*CommandList[CmdNumber].CommandPointer)();
          return;  
    }
  }
  PrintMessage("Unknown command '%s'\n", Parameter[0].c_str());
}


// Print help
void User::cmd_help() {

  for(unsigned int i=0; i<sizeof(CommandList)/sizeof(CL_Struct); i++) {
    PrintMessage("%-10s%s\n", CommandList[i].Name, CommandList[i].Help);
  }
  
  PrintMessage("\nUse '?' as argument to get more extensive help.\n"
        "Commands 'pixel' and 'channel' allow and arbitary number of argument pairs.\n"
        "Items in <> are mandatory, in [] optional, | indicates mutual exclusive or.\n"
    "Ranges can be 'all', a single number or in the form 'a-b'.\n"); 
} 

//
// Synchronize crate
//
void User::cmd_synch() {

  if (Dev->Synch()) PrintMessage("Synchronized crate\n");
  else PrintMessage("Failed to synchronize crate\n");
}

//
// Set new bias voltage
//
void User::cmd_hv() {

  unsigned int Channel, Errors = 0;
  double Double;
  struct Range Chan, Pixel;
  map<unsigned int, double> Voltages;
  vector<unsigned int> Channels;

  // Loop over all parameters
  for (unsigned int n=1; n < Parameter.size()-1; n+=2) {

        // Convert voltage value and check format 
        if (!ConvertToDouble(Parameter[n+1], &Double) && !Match(Parameter[n+1], "default") && !Match(Parameter[n+1], "info")) {
          PrintMessage("Error: Wrong number format for voltage setting\n");
          continue;
        }

        // Extract affected channels for this argument pair
        Channels.clear();

        // Pixel identification?
        if (Match(Parameter[0], "pixel")) {
          Pixel.Min = 0;
          Pixel.Max = 1439;

          if (!ConvertToRange(Parameter[n], Pixel)) {
                PrintMessage("Pixel ID out-of-range for parameter %d, skipping channel\n", n);
                continue;
          }
          
          for (int i=Pixel.Min; i<=Pixel.Max; i++) {
                Channel = PixMap->Pixel_to_HVboard(i)*NUM_CHANNELS + PixMap->Pixel_to_HVchannel(i);
                
                // Skip if pixel ID or corresponding channels not existing 
                if (PixMap->Pixel_to_HVcrate(i) == 0 && Channel<MAX_NUM_BOARDS*NUM_CHANNELS) {
                  Channels.push_back(Channel);
                }
          }
        }
        // Channel identification
        else {
          Chan.Min = 0;
          Chan.Max = MAX_NUM_BOARDS*NUM_CHANNELS-1;       

          if (!ConvertToRange(Parameter[n], Chan)) {
                PrintMessage("Numeric conversion or out-of-range error for parameter %d, skipping channel\n", n);
                continue;
          }
          
          for (int i=Chan.Min; i<=Chan.Max; i++) Channels.push_back(i);   
        }
  
        // Loop over all given channels
        for (unsigned int i=0; i<Channels.size(); i++) {
          Channel = Channels[i];

          // Should only information be printed?
          if (Match(Parameter[n+1], "info")) {
                PrintMessage("Channel %d ", Channel);
                if (!Dev->Present[Channel]) PrintMessage(" is not present in crate\n");
                else PrintMessage("is on board %d, board channel %d\n", Channel/32, Channel%32);

                // Print pixel information
                vector<unsigned int> List = PixMap->HV_to_Pixel(0, Channel/NUM_CHANNELS, Channel%NUM_CHANNELS);
                PrintMessage("\n  Default voltage: %.2f    Pixel IDs: ", Channel < DefaultVoltage.size() ? DefaultVoltage[Channel] : 0);
                for (unsigned int j=0; j<List.size(); j++) PrintMessage("%u ", List[j]);
                if (List.empty()) PrintMessage("none");

                // Print voltage and current
                PrintMessage("\n  Voltage setpoint: %.2f V (DAC %u)    Current: %.2f uA ", Dev->GetVoltage(Channel), Dev->GetDAC(Channel), Dev->GetCurrent(Channel));

                if (Dev->OC[Channel]) PrintMessage("(overcurrent)\n");
                else PrintMessage("\n");

                continue;
          }

          // Get current voltage on first change of a channel
          if (Voltages.count(Channel) == 0) Voltages[Channel] = Dev->GetVoltage(Channel);

          // Voltage change (number starts with + oder -) ignored if voltage is zero
          if (Parameter[n+1][0]=='+' || Parameter[n+1][0]=='-') if (Voltages[Channel] == 0) continue;
        
          // Should the default value be set?
          if (Match(Parameter[n+1], "default")) {
                if (Channel < DefaultVoltage.size()) Double = DefaultVoltage[Channel];
                else Double = 0;
          }
          
          // Relative or absolute change?
          if (Parameter[n+1][0]=='+' || Parameter[n+1][0]=='-') Voltages[Channel] += Double;
          else Voltages[Channel] = Double;
        } // Channels
  } // Loop over command argument

  // Ramp voltages and update DIM services
  Errors += RampVoltages(Voltages);
  Dev->UpdateDIM();

  // Error message only if not yet too many errors
  if (Errors > 0) {
        if (Dev->ErrorCount > MAX_ERR_COUNT) return;
    Message(ERROR, "%d errors occurred from SetChannels()", Errors);
  }
}

//
// Load bias settings from file
//
void User::cmd_load() {

  char Buffer[MAX_COM_SIZE];
  int Errors = 0;
  unsigned int Channel;
  double Value;
  FILE *File;
  map<unsigned int, double> Voltages;

  // Open file
  if ((File=fopen(Parameter[1].c_str(), "r")) == NULL) {
    PrintMessage("Error: Could not open file '%s' (%s)\n", Parameter[1].c_str(), strerror(errno));
    return;
  }

  // Scan through file line by line
  while (fgets(Buffer, sizeof(Buffer), File) != NULL) if (Match(Dev->Name, Buffer)) {
        PrintMessage("Found bias settings for crate %s\n\r", Dev->Name);

        Voltages.clear();
        Channel = 0;
        while (fscanf(File, "%lf", &Value)==1 && Channel<MAX_NUM_BOARDS*NUM_CHANNELS) {
          Voltages[Channel++] = Value;
        }

        // Ramp channels
        Errors += RampVoltages(Voltages);

    // Update DIM service
        Dev->UpdateDIM();

        if (ferror(File) != 0) {
          PrintMessage("Error reading DAC value from file, terminating. (%s)\n",strerror(errno));
      return;
        }
        else PrintMessage("\nFinished updating board\n");
  } // if()
            
  if (Errors != 0) PrintMessage("Warning: %d error(s) occurred\n", Errors);
  if (fclose(File) != 0) PrintMessage("Error: Could not close file '%s'\n", Parameter[1].c_str());
}
             
//
// Reset crate
//
void User::cmd_reset() {

  if (Dev->SystemReset()) PrintMessage("System reset of crate\n");
  else PrintMessage("Error: Could not reset crate\n");
}

//
// Read channel
//
void User::cmd_gs() {

  double Voltage;

  if (!ConvertToDouble(Parameter[1], &Voltage)) {
    PrintMessage("Error: Wrong number format\n");
        return;
  }
  
  if (!Dev->GlobalSet(Voltage)) {
        PrintMessage("Error: Could not global set crate\n");
  }  
}

//
// Save bias settings of all boards
//
void User::cmd_save() {

  FILE *File;
  time_t Time = time(NULL);

  if ((File = fopen(Parameter[1].c_str(), "w")) == NULL) {
    PrintMessage("Error: Could not open file '%s' (%s)\n", Parameter[1].c_str(), strerror(errno));
    return;
  }

  fprintf(File,"********** Bias settings of %s **********\n\n", ctime(&Time));
  fprintf(File, "%s\n\n", Dev->Name);

  for (unsigned int j=0; j<MAX_NUM_BOARDS*NUM_CHANNELS; j++) fprintf(File,"%.3f ", Dev->GetVoltage(j));
  fprintf(File, "\n");

  if (fclose(File) != 0) {
    PrintMessage("Error: Could not close file '%s' (%s)\n", Parameter[1].c_str(), strerror(errno));  
  }
}

//
// Set operation mode
//
void User::cmd_mode() {

  if (Match(Parameter[1], "static")) Mode = mode_static;
  else {
    Mode = mode_dynamic;
        Dev->SetRefCurrent();
  }
} 

//
// Calibrate current measurement
//
void User::cmd_calib() {

  map<unsigned int, double> Voltages, Initial, Current[2];
  int Errors, Num;
  double Volt[2];

  // Clear current calibration values?
  if (Match(Parameter[1], "invalidate")) {
        PrintMessage("Current calibration invalidated\n");
        R.assign(MAX_NUM_BOARDS*NUM_CHANNELS, numeric_limits<double>::infinity());
        I0.assign(MAX_NUM_BOARDS*NUM_CHANNELS, 0);
        return;
  }

  // Check number of parameters and convert
  if (Parameter.size() != 4) {
        PrintMessage("Error: Number of parameters incorrect\n");
        return;
  }

  if (!ConvertToDouble(Parameter[1], &Volt[0]) || !ConvertToDouble(Parameter[2], &Volt[1])) {
    PrintMessage("Error: Wrong number format for voltages\n");
        return;
  }

  if (!ConvertToInt(Parameter[3], &Num)) {
    PrintMessage("Error: Wrong number format for number of iterations\n");
        return;
  }

  // Check if infinity can be represented for double
  if (!numeric_limits<double>::has_infinity) {
        PrintMessage("Cannot perform calibration, double cannot represent infinity\n");
        return;
  }

  // Save initial voltages
  for (unsigned int i=0; i<MAX_NUM_BOARDS*NUM_CHANNELS; i++) Initial[i] = Dev->GetVoltage(i);

  // Make current measurements at given voltages
  for (unsigned int Round=0; Round<2; Round++) {
        // Set voltage
        for (unsigned int i=0; i<MAX_NUM_BOARDS*NUM_CHANNELS; i++) Voltages[i] = Volt[Round];

        if ((Errors = RampVoltages(Voltages)) != 0) {
          PrintMessage("%d errors occurred while ramping to %.2f V\n", Errors, Volt[Round]);
          return;
        }
        else PrintMessage("Ramped all channels to %.2f V\n", Volt[Round]);

        // Read currenty repeatably
        for (int Count=0; Count<Num; Count++) {
          if (Count % 20 == 0) PrintMessage("Reading current iteration %d   \r", Count);
          if (!Dev->ReadAll()) {
                PrintMessage("\nError from ReadAll()\n");
                return;
          }
          for (unsigned int i=0; i<MAX_NUM_BOARDS*NUM_CHANNELS; i++) {
                Current[Round][i] += Dev->GetCurrent(i)/Num;
          }
        }
  } // for()


  // Set initial voltages
  if ((Errors = RampVoltages(Initial)) != 0) {
        PrintMessage("%d errors occurred while ramping back to inital voltages\n", Errors);
        return;
  }
  else PrintMessage("Ramped all channels back to inital voltages\n");

  // Calculate calibration constants (R in MOhm)
  for (unsigned int i=0; i<MAX_NUM_BOARDS*NUM_CHANNELS; i++) {
    R[i] = (Volt[1] - Volt[0]) / (Current[1][i]-Current[0][i]);
        I0[i] = Current[0][i] - Volt[0]/R[i];
  }
}

//
// Print status
//
void User::cmd_status() {

  enum {M_V,M_DAC,M_I,M_R,M_I0,M_notset} M = M_notset;

  // Overview information
  PrintMessage("Update delay:   %2d sec    Time out:    %.2f sec    Minium reset delay:   %u sec\n",
        min(atoi(GetConfig("UpdatePeriod").c_str()), 1), atof(GetConfig("TimeOut").c_str()),
        atoi(GetConfig("MinResetPeriod").c_str()));
  PrintMessage("Voltage limit:   %.2f V  Ramp speed:  %.2f V/10 ms\n",
        atof(GetConfig("VoltageLimit").c_str()), atof(GetConfig("RampSpeed").c_str()));
  
  if (Dev == NULL) return;

  // Details
  PrintMessage("\nCRATE %s   Wrap counter: %s (%d)  Reset: %s  Error count: %d %s\n ",
          Dev->Name, Dev->WrapOK ? "ok":"error", Dev->WrapCount, 
          Dev->ResetHit ? "yes" : "no", Dev->ErrorCount, Dev->Disabled ? "(DISABLED)":"");

  // Read all channels
  if (!Dev->ReadAll()) {
        PrintMessage("Could not update status, ReadAll() failed\n");
        return;
  }

  // Voltage or current list
  if (Match(Parameter[0], "voltage")) {
        if (Parameter.size() == 1) M = M_V;
        else M = M_DAC;
  }
  else if (Match(Parameter[0], "current")) M = M_I;
  else if (Parameter.size() == 2) {
        if (Match(Parameter[1], "R")) M = M_R;
        if (Match(Parameter[1], "I0")) M = M_I0;
  }

  if (M == M_notset) return;
  if (M == M_V) PrintMessage("Channel voltages (in V)");
  if (M == M_DAC) PrintMessage("Channel voltages (in DAC values)");
  if (M == M_R) PrintMessage("Channel internal resistance  (in kOhm)");
  if (M == M_I0) PrintMessage("Channel current offset (in uA)");
  if (M == M_I) PrintMessage("Channel currents (in uA)");

  for (unsigned int j=0; j<MAX_NUM_BOARDS*NUM_CHANNELS; j++) {
        if (j%12 == 0) PrintMessage("\n%3.1d:  ", j);
        if (!Dev->Present[j]) PrintMessage("    -");
    else if (M == M_V) PrintMessage("%#5.2f", Dev->GetVoltage(j));
        else if (M == M_DAC) PrintMessage("%5d", Dev->GetDAC(j));
        else if (M == M_R) PrintMessage("%#5.2f", R[j]*1000);
        else if (M == M_I0) PrintMessage("%#5.2f", I0[j]);
        else if (M == M_I) PrintMessage("%#5.1f", Dev->GetCurrent(j) - Dev->GetVoltage(j)/R[j] - I0[j]); 

        // Print overcurrent marker
        PrintMessage("%s ", Dev->OC[j] ? "*":" ");
  }
  PrintMessage("\n");
} 

//
// Exit program (Signal makes readline return and sets ExitRequest)
//
void User::cmd_exit() {

  pthread_kill(MainThread, SIGTERM);
}

//
// Execute shell command
//
void User::cmd_shell() {

  if (system(Parameter[1].c_str()) == -1) PrintMessage("Error with system() call\n");
}


//
// Print message to screen and to DIM text service
//
void User::PrintMessage(const char *Format, ...) {

  static char Error[] = "vasprintf() failed in PrintMessage()";
  char *Text;

  // Evaluate arguments    
  va_list ArgumentPointer;
  va_start(ArgumentPointer, Format);
  if (vasprintf(&Text, Format, ArgumentPointer) == -1) Text = Error;
  va_end(ArgumentPointer);

  if (strlen(Text) == 0) return;
 
  // Print to console
  printf("%s", Text);
  fflush(stdout);
  if (Text[strlen(Text)-1] == '\n') rl_on_new_line(); // New prompt

  // Send to DIM text service
  ConsoleOut->updateService(Text); 

  // Free old text
  if (ConsoleText != Error) free(ConsoleText);
  ConsoleText = Text; 
}


// Ramp to new voltage with given maximum step
unsigned int User::RampVoltages(map<unsigned int, double> Voltages) {

  map<unsigned int, double> Target;
  int Errors = 0;
  double V, Lim, MaxDiff = atof(GetConfig("RampSpeed").c_str());

  while (!Voltages.empty() && Errors < MAX_ERR_COUNT) {
        // Voltage limit evaluate here in case of asynchronous update in config file
    Lim = atof(GetConfig("VoltageLimit").c_str());

        // Remove channels already at target or at voltage limit
        for (map<unsigned int, double>::iterator it = Voltages.begin(); it != Voltages.end(); ++it) {   
          // Channel at target?
          if (fabs(Dev->GetVoltage(it->first)-it->second) < 0.001) Voltages.erase(it);
          // Channel at voltage limit?
          if (it->second > Lim && Dev->GetVoltage(it->first) == Lim) Voltages.erase(it);
          if (it->second < 0 && Dev->GetVoltage(it->first) == 0) Voltages.erase(it);
        }
        
        // Limit voltage changes to MaxDiff
        Target = Voltages;
        for (map<unsigned int, double>::iterator it = Target.begin(); it != Target.end(); ++it) {
          V = Dev->GetVoltage(it->first);
          // Ramp up
          if ((V < it->second) && (V + MaxDiff < it->second)) it->second = V + MaxDiff;
          // Ramp down
          if ((V > it->second) && (V - MaxDiff > it->second)) it->second = V - MaxDiff;
        }       
        
        // Set channels to next target and wait 10 ms
        if (!Dev->SetChannels(Target)) Errors++;
        usleep(10000);
  }
  
  return Errors;
}


//
// Check status
//
void User::Monitor() {

  int Ret;

  // End if no crate available
  if (Dev == NULL) return;

  while (!ExitRequest) {
        // Wait (this is the only allowed cancelation point)
        if ((Ret=pthread_setcancelstate(PTHREAD_CANCEL_ENABLE, NULL)) != 0) {
          Message(FATAL, "pthread_setcancelstate() failed (%s)", strerror(Ret));
        }
        sleep(min(atoi(GetConfig("UpdatePeriod").c_str()), 1));
        if ((Ret=pthread_setcancelstate(PTHREAD_CANCEL_DISABLE, NULL)) != 0) {
          Message(FATAL, "pthread_setcancelstate() failed (%s)", strerror(Ret));
        }

        // Check crate
    if (Dev->Disabled) continue;

        // Read all channels
    if (!Dev->ReadAll()) {
      Message(ERROR, "Monitor thread could not read status, ReadAll() failed\n");
          continue;
    }

        // Check if crate push button was hit
    if (Dev->ResetHit) {
      Message(INFO, "Manual reset of crate, setting voltages to zero and issuing system reset");
          if (!Dev->GlobalSet(0)) Message(ERROR, "Global set to zero voltage of crate failed");
          if (!Dev->SystemReset()) Message(ERROR, "System reset of crate failed");
    }

        // Check for overcurrent and set voltage to zero if occurred
        map<unsigned int, double> Voltages;

    for (unsigned int j=0; j<MAX_NUM_BOARDS*NUM_CHANNELS; j++) if (Dev->OC[j]) Voltages[j] = 0;
        if (!Voltages.empty()) {
          if (!Dev->SetChannels(Voltages)) Message(ERROR, "Error setting voltage to zero for channels with overcurrent");
          Dev->UpdateDIM();
        }

        if (Mode == mode_dynamic) Dev->AdaptVoltages();
  } // while
}

// Call monitor loop inside class
void User::LaunchMonitor(User *m) {

  m->Monitor();
}


//
// Check if two strings match (min 1 character must match)
//
bool User::Match(string str, const char *cmd) {

  return strncasecmp(str.c_str(),cmd,strlen(str.c_str())==0 ? 1:strlen(str.c_str())) ? false:true;
}

//
// Conversion function from string to double or int
//
// Return false if conversion did not stop on whitespace or EOL character
bool User::ConvertToDouble(string String, double *Result) {

  char *EndPointer;
  
  *Result = strtod(String.c_str(), &EndPointer);
  if(!isspace(*EndPointer) && *EndPointer!='\0') return false;
  return true;
}

bool User::ConvertToInt(string String, int *Result) {

  char *EndPointer;
  
  *Result = (int) strtol(String.c_str(), &EndPointer, 0);
  if(!isspace(*EndPointer) && *EndPointer!='\0') return false;
  return true;
}

//
// Interprets a range
//
bool User::ConvertToRange(string String, struct User::Range &R) {

  int N=0, M=0; // Init to avoid compiler warning

  // Full range
  if (Match(String, "all")) return true;

  // Single number
  if (ConvertToInt(String, &N)) {
        if (N>= R.Min && N<=R.Max) {
          R.Max = R.Min = N;
          return true;
        }
        return false;
  }
  
  // Range a-b
  vector<string> V = EvidenceServer::Tokenize(String, "-");
  if (V.size()==2 && ConvertToInt(V[0], &N) && ConvertToInt(V[1], &M) && N>=R.Min && M<=R.Max) {
        R.Min = N;
        R.Max = M;
        return true;
  }
  
  return false;
}