Ejemplo n.º 1
0
void Nuclide::setIsomerEnergy()
{
  if ( st == 0 )
    return;

  extractValue(full_data,39,46,is_nrg);
  // Some isomers(3 in total) are measured via beta difference so come out -ve
  is_nrg = fabs(is_nrg);

  extractValue(full_data,48,56,dis_nrg);
}
Ejemplo n.º 2
0
void Settings::update() {
    std::string name;
    std::string value;

    m_values.clear();

    std::ifstream settings(m_fileName.c_str());
    if (!settings.is_open()) {
        std::cout << "Failed to open " << m_fileName << "\n";
        return;
    }

    do {
        std::getline(settings, m_rawStr);

        m_index = 0;
        name = extractKey();
        value = extractValue();

        // Add name-value pair to map
        m_values[name] = value;
    } while (!settings.eof());

    settings.close();

    std::cout << "Settings loaded from " << m_fileName << "\n";
}
Ejemplo n.º 3
0
bool JsonParser::extractElement(JsonNode &node, char terminator)
{
	if (!extractValue(node))
		return false;

	if (!extractWhitespace())
		return false;

	bool comma = (input[pos] == ',');
	if (comma )
	{
		pos++;
		if (!extractWhitespace())
			return false;
	}

	if (input[pos] == terminator)
	{
		//FIXME: MOD COMPATIBILITY: Too many of these right now, re-enable later
		//if (comma)
			//error("Extra comma found!", true);
		return true;
	}

	if (!comma)
		error("Comma expected!", true);

	return true;
}
Ejemplo n.º 4
0
JsonNode JsonParser::parse(std::string fileName)
{
	JsonNode root;

	if (input.size() == 0)
	{
		error("File is empty", false);
	}
	else
	{
		if (!Unicode::isValidString(&input[0], input.size()))
			error("Not a valid UTF-8 file", false);

		extractValue(root);
		extractWhitespace(false);

		//Warn if there are any non-whitespace symbols left
		if (pos < input.size())
			error("Not all file was parsed!", true);
	}

	if (!errors.empty())
	{
		logGlobal->warnStream()<<"File " << fileName << " is not a valid JSON file!";
		logGlobal->warnStream()<<errors;
	}
	return root;
}
Ejemplo n.º 5
0
static Variant HHVM_METHOD(ResourceBundle, next) {
  FETCH_RSRC(data, this_);
  if (!data->iterNext()) {
    return init_null();
  }
  UErrorCode error = U_ZERO_ERROR;
  return extractValue(data, data->iterCurrent(error));
}
Ejemplo n.º 6
0
void Nuclide::setHalfLife()
{
  std::string lifetime;

  lifetime = (full_data.size() < 59) ? "no_units" : full_data.substr(60,9);

  if (   lifetime.find("p-unst") != std::string::npos
      || lifetime.find_first_not_of(" ") == std::string::npos
      || lifetime.find("R") != std::string::npos
      )
    {
      lifetime = "no_units";
    }

  size_t found = lifetime.find_first_of("<>~");
  if ( found != std::string::npos )
    {
      lifetime.at(found) = ' ';
    }

  extractValue(lifetime,0,9,hl);

  if ( hl < 0.0001 )
    {
      hl = (lifetime == "no_units") ? 1.0e-24 : 1.0e24;
    }
  else
    {
      std::string halfLifeUnit = full_data.substr(69,2);

      if( halfLifeUnit.find_first_not_of(' ') == std::string::npos )
        {
          halfLifeUnit = "ys";
        }

      if      (halfLifeUnit == "ys") hl*=1.0e-24;
      else if (halfLifeUnit == "zs") hl*=1.0e-21;
      else if (halfLifeUnit == "as") hl*=1.0e-18;
      else if (halfLifeUnit == "ps") hl*=1.0e-12;
      else if (halfLifeUnit == "ns") hl*=1.0e-09;
      else if (halfLifeUnit == "us") hl*=1.0e-06;
      else if (halfLifeUnit == "ms") hl*=1.0e-03;
      else if (halfLifeUnit == " s") hl*=1.0;
      else if (halfLifeUnit == " m") hl*=60.0;
      else if (halfLifeUnit == " h") hl*=3600.0;
      else if (halfLifeUnit == " d") hl*=86400.0;
      else if (halfLifeUnit == " y") hl*=31557600.0;
      else if (halfLifeUnit == "ky") hl*=31557600*1.0e03;
      else if (halfLifeUnit == "My") hl*=31557600*1.0e06;
      else if (halfLifeUnit == "Gy") hl*=31557600*1.0e09;
      else if (halfLifeUnit == "Ty") hl*=31557600*1.0e12;
      else if (halfLifeUnit == "Py") hl*=31557600*1.0e15;
      else if (halfLifeUnit == "Ey") hl*=31557600*1.0e18;
      else if (halfLifeUnit == "Zy") hl*=31557600*1.0e21;
      else if (halfLifeUnit == "Yy") hl*=31557600*1.0e24;
    }
}
Ejemplo n.º 7
0
    virtual void output(Entity* entity, QIODevice& file) const{
        auto v = extractValue(DOCUMENT_IMAGE);

        for(auto e : v.keys())
        {
          qDebug() << e << "," << v.value(e) << '\n';
        }

    }
Ejemplo n.º 8
0
double DurationSpinBox::valueFromText( const QString & text ) const
{
    QString s = extractValue( text ).remove( KGlobal::locale()->thousandsSeparator() );
    bool ok = false;
    double v = KGlobal::locale()->readNumber( s, &ok );
    if ( ! ok ) {
        v = QDoubleSpinBox::valueFromText( s );
    }
    return v;
}
void handleServerMessage(char * message) {
	char * str;
	if (strstr(message, "ERROR") != NULL) {
		state = 0;
		printf("Error while Registering");
	} else if (strstr(message, "Registered") != NULL) {
		state = 1;
		printf("Registered Successfully");
	} else if (strstr(message, "Switch") != NULL) {
		str = extractValue(message);
		if (strcmp(str,"ON") == 0) {
			state = 1; 
		} else {
			state = 0;
		}
	} else if (strstr(message, "setInterval") != NULL) {
		str = extractValue(message);
		interval = atoi(str);
	}
		
}
Ejemplo n.º 10
0
/*
*	Extract 8bit Value to operand1
*
*	Operation:
*		if nothing is throw
*
*  Return:
*		operand1 value
*
*/
int operand1ExtractValue(String *arguments) {
    ErrorCode error;
    int operand1;

    Try{
        operand1 = extractValue(arguments);
    } Catch(error) {
        Throw(error);
    }

    return operand1;
}
//---------------------------------------------------
bool skInterpreter::extractFieldArrayValue(skStackFrame& frame,skRValue& robject,const skString& field_name,skExprNode * array_index,const skString& attrib,skRValue& ret)
//---------------------------------------------------
{
    skRValue array_field;
    SAVE_VARIABLE(array_field);
    skString blank;
    bool found=extractValue(frame,robject,field_name,blank,array_field);
    if (found) {
        extractArrayValue(frame,array_field,array_index,attrib,ret);
    }
    RELEASE_VARIABLE(array_field);
    return found;
}
Ejemplo n.º 12
0
/**
 *
 *	operand1ExtractValue
 *
 *	Try to get the operand1 and return operand1. Catch e and throw error.
 *	
 *	Input	:
 *		arguements
 *		
 *	Return	:
 *		operand1
 *
 **/
int operand1ExtractValue(String *arguments){
	int operand1;
	ErrorCode e;
	
	Try{
		operand1 = extractValue(arguments);
	}Catch(e){ 
        printf("Error operand1 Throw");
		Throw(e);
	} 
	
	return operand1;
}
Ejemplo n.º 13
0
bool VehicleParam::readLine(std::ifstream& ifs, std::string identifyName, float& outValue)
{
	std::string str;
	do 
	{
		std::getline(ifs, str);
		if (ifs.eof())
			return false;

	} while (str.empty());//jump over the null line

	return extractValue(str, identifyName, outValue);
}
Ejemplo n.º 14
0
void NCDParser::publishLaserMessage(const std::vector<std::string>& tokens,
                                    const std::string& laserFrame,
                                    const ros::Publisher& publisher)
{
  ROS_DEBUG("Laser message");

  sensor_msgs::LaserScan scan;

  double time = extractValue(tokens[3], "time=");

  scan.header.stamp    = ros::Time(time);
  scan.header.frame_id = laserFrame;

  scan.angle_min       = extractValue(tokens[3], "minAngle=") * DEG_TO_RAD; 
  scan.angle_max       = extractValue(tokens[3], "maxAngle=") * DEG_TO_RAD; 
  scan.angle_increment = extractValue(tokens[3], "angRes=")   * DEG_TO_RAD; 
  scan.range_min       = RANGE_MIN;
  scan.range_max       = RANGE_MAX;
  scan.ranges          = extractArray(tokens[3], "Range=[181]");
  scan.intensities     = extractArray(tokens[3], "Reflectance=[181]");

  publisher.publish(scan);
}
Ejemplo n.º 15
0
void NCDParser::publishTfMessages(const std::vector<std::string>& tokens)
{
  ROS_DEBUG("Tf message");

  // extract time
  double time = extractValue(tokens[3], "time=");

  // extract x, y, theta
  std::vector<float> xytheta = extractArray(tokens[3], "Pose=[3x1]");
  double x     = xytheta[0];
  double y     = xytheta[1];
  double z     = 0.0;
  double theta = xytheta[2];       

  // extract Pitch
  double pitch = extractValue(tokens[3], "Pitch=");

  // extract Roll
  double roll = extractValue(tokens[3], "Roll=");

  btQuaternion rotation;
  rotation.setRPY (roll, pitch, theta);
  worldToOdom_.setRotation (rotation);

  btVector3 origin;
  origin.setValue (x, y, z);
  worldToOdom_.setOrigin (origin);

  tf::StampedTransform worldToOdomStamped(worldToOdom_, ros::Time(time), worldFrame_, odomFrame_);
  tfBroadcaster_.sendTransform(worldToOdomStamped);

  tf::StampedTransform odomToLeftLaserStamped(odomToLeftLaser_, ros::Time(time), odomFrame_, leftLaserFrame_);
  tfBroadcaster_.sendTransform(odomToLeftLaserStamped);

  tf::StampedTransform odomToRightLaserStamped(odomToRightLaser_, ros::Time(time), odomFrame_, rightLaserFrame_);
  tfBroadcaster_.sendTransform(odomToRightLaserStamped);
}
Ejemplo n.º 16
0
static Variant HHVM_METHOD(ResourceBundle, get,
                           const Variant& index,
                           bool fallback) {
  FETCH_RSRC(data, this_);
  UErrorCode error = U_ZERO_ERROR;
  icu::ResourceBundle child(error);
  if (U_FAILURE(error)) {
    data->setError(error, "Unable to generate default resource bundle");
    return false;
  }
  if (index.isInteger()) {
    child = data->resource()->get((int32_t)index.toInt64(), error);
    if (U_FAILURE(error)) {
      data->setError(error, "Cannot load resource element %d",
                            (int)index.toInt64());
      return init_null();
    }
  } else if (index.isString()) {
    child = data->resource()->get(index.toString().c_str(), error);
    if (U_FAILURE(error)) {
      data->setError(error, "Cannot load resource element '%s'",
                            index.toString().c_str());
      return init_null();
    }
  } else {
    data->setError(U_ILLEGAL_ARGUMENT_ERROR,
                   "resourcebundle_get: index should be integer or string");
    return init_null();
  }

  if (!fallback &&
      ((error == U_USING_FALLBACK_WARNING) ||
       (error == U_USING_DEFAULT_WARNING))) {
    UErrorCode dummy = U_ZERO_ERROR;
    auto locale = data->resource()->getLocale(ULOC_ACTUAL_LOCALE, dummy);
    if (index.isInteger()) {
      data->setError(error,
                     "Cannot load element %d without fallback from to %s",
                     (int)index.toInt64(), locale.getName());
    } else {
      data->setError(error,
                     "Cannot load element %s without fallback from to %s",
                     index.toString().c_str(), locale.getName());
    }
    return init_null();
  }

  return extractValue(data, child);
}
Ejemplo n.º 17
0
    virtual void output(Entity* entity, QIODevice& iodevice) const{
        auto v = extractValue(EYOU_TAG);

        QString url = v["URL"];
        if (url.isEmpty()){
            return;

        }
//      <iframe width="560" height="315" src="https://www.youtube.com/embed/vlDYoATH_jI" frameborder="0" allowfullscreen></iframe>
      //<iframe width="560" height="315" src="https://www.youtube.com/embed/vlDYoATH_jI" frameborder="0" allowfullscreen>
    //    <iframe width="560" height="315" src="https://youtu.be/vlDYoATH_jI" frameborder="0" allowfullscreen></iframe>

        iodevice.write(QString("<iframe width=\"560\" height=\"315\" src=\"https://www.youtube.com/embed/").append(url).append("\" frameborder=\"0\" allowfullscreen></iframe>").toUtf8());

    }
Ejemplo n.º 18
0
void ConfigFile::extractContents(const std::string &line)
{
    std::string temp = line;
    temp.erase(0, temp.find_first_not_of("\t "));
    size_t sepPos = temp.find('=');

    std::string key, value;
    extractKey(key, sepPos, temp);
    extractValue(value, sepPos, temp);

    if (!keyExists(key))
        contents.insert(std::pair<std::string, std::string > (key, value));
    else
        std::cout << "CFG: Can only have unique key names!\n" << std::endl;
}
//---------------------------------------------------
void  skInterpreter::makeMethodCall(skStackFrame& frame,skRValue& robject,const skString& method_name,skExprNode * array_index,const skString& attribute, skExprListNode * exprs,skRValue& ret)
//---------------------------------------------------
{
    skString checked_method_name=checkIndirectId(frame,method_name);
    if (robject.type()==skRValue::T_Object) {
        skRValueArray args;
        SAVE_VARIABLE(robject);
        skExprListIterator iter(exprs->getExprs());
        skExprNode * expr=0;
        while ((expr=iter())!=0) {
#ifndef EXCEPTIONS_DEFINED
            if (frame.getContext().getError().getErrorCode()!=skScriptError::NONE)
                break;
#endif
            args.append(evaluate(frame,expr));
        }
#ifndef EXCEPTIONS_DEFINED
        if (frame.getContext().getError().getErrorCode()==skScriptError::NONE) {
#endif
            if (m_Tracing)
                trace(skString::addStrings(frame.getLocation().ptr(),s_colon,skString::from(frame.getLineNum()+1).ptr(),s_colon,checked_method_name.ptr(),s_FunctionEnd));
            // call to this object
            bool bRet=robject.obj()->method(checked_method_name,args,ret,frame.getContext());
            if (bRet==false)
                runtimeError(frame,skString::addStrings(s_MethodStart,checked_method_name.ptr(),s_NotFound));
            // case foo()[i]
            if (array_index) {
                skRValue array_value;
                bRet=extractArrayValue(frame,ret,array_index,attribute,array_value);
                ret=array_value;
            } else {
                // case foo():attr
                if (attribute.length()) {
                    skRValue attr_value;
                    skString blank;
                    bRet=extractValue(frame,ret,blank,attribute,attr_value);
                    ret=attr_value;
                }
            }
#ifndef EXCEPTIONS_DEFINED
        }
#endif
        RELEASE_VARIABLE(robject);
    } else {
        runtimeError(frame,skString::addStrings(s_CannotCallMethod,checked_method_name.ptr(),s_OnANonObject));
    }
}
Ejemplo n.º 20
0
/*
*	Extract 3 bit value to operand2
*	
*	Operation:
*		To Catch No Argument and Empty Argument Value,extract value
*
*	Throw:
*		NO argument
*		Not empty argument but illegal argument
*
*  Return:
*		operand2 value
*
*/
int extract3BitsValue(String *arguments){
	ErrorCode error;
	int operand2;
	
	Try{
		operand2 = extractValue(arguments);
	}Catch(error){
		if(error == ERR_NO_ARGUMENT){
				Throw(error);
		}else if(error != ERR_EMPTY_ARGUMENT){
			if(error == ERR_ILLEGAL_ARGUMENT){
				Throw(error);
			}
		}
	}
	
	return operand2;
}
Ejemplo n.º 21
0
QValidator::State DurationSpinBox::validate ( QString & input, int & pos ) const
{
    //kDebug(planDbg())<<input;
    KDoubleValidator validator( minimum(), maximum(), decimals(), 0 );
    if ( input.isEmpty() ) {
        return validator.validate ( input, pos );
    }
    QString s = extractUnit( input );
    if ( s.isEmpty() ) {
        return validator.validate ( input, pos );
    }
    int idx = Duration::unitList( true ).indexOf( s ); 
    if ( idx < m_maxunit || idx > m_minunit ) {
        return QValidator::Invalid;
    }
    s = extractValue( input );
    int p = 0;
    return validator.validate ( s, p ); // pos doesn't matter
}
Ejemplo n.º 22
0
void Config::extractLine(const std::string& section, const std::string& line, std::ifstream& file, int& lineNb)
{
    std::string temp = line;
    temp.erase(0, temp.find_first_not_of(" \t\r\n\v\f"));
    size_t sepPos = temp.find('=');

    std::string key;
    std::string value;
    extractKey(key, sepPos, temp);
    key = section.substr(1, section.length()-2) + "." + key;
    extractValue(value, sepPos, temp);

    if (!isKeyExists(key)) {
        _map.insert(std::pair<std::string, std::string>(key, value));
    }
    else {
		Log(LOG_TYPE::ERROR) << "Config: Can only have unique key names!";
    }
}
Ejemplo n.º 23
0
int operandExtract1BitsValue(String *arguments){
	ErrorCode e;
	int operand1;
	
	Try{
		operand1 = extractValue(arguments);
	}Catch(e){ 
        if(e == ERR_NO_ARGUMENT || e == ERR_EMPTY_ARGUMENT){
			operand1 = 0;
			return operand1;
		}else if(e == ERR_ILLEGAL_ARGUMENT){
			Throw(e);
		}
	}
	
	operand1 = operand1 & 0x01;
	
	return operand1;
}
Ejemplo n.º 24
0
void ConfigFile::extractContents(const std::string &line)
{
	// called from parse_line(), validated there

	std::string tmp = line;
	// remove leading whitespace
	tmp.erase(0, tmp.find_first_not_of("\t "));
	size_t sep_pos = tmp.find('=');

	std::string key, value;
	extractKey(key, sep_pos, tmp);
	extractValue(value, sep_pos, tmp);

	if (!containsKey(key))
	{
		contents.insert(std::pair<std::string, std::string>(key, value));
	}
	else
	{
		ConfigUtil::warn(key + " was declared at least twice in configuration file.");
	}
}
//---------------------------------------------------
void skInterpreter::followIdList(skStackFrame& frame,skIdListNode * idList,skRValue& object)
//---------------------------------------------------
{
    skString blank;
    // skip down the id.id.id list, resolving each as we go along, we exclude the final id in the list
    skIdNode * idNode=idList->getId(0);
    skString name=idNode->getId();
    //  trace("followIdList: %s - %d ids\n",(const char *)name,idList->m_Ids.entries());
    if (idNode->getExprs()==0)
        object=findValue(frame,name,idNode->getArrayIndex(),blank);
    else {
        skRValue caller;
        SAVE_VARIABLE(caller);
        caller.assignObject(frame.getObject(),false);
        makeMethodCall(frame,caller,name,idNode->getArrayIndex(),blank,idNode->getExprs(),object);
        RELEASE_VARIABLE(caller);
    }
    for (unsigned int i=1; i<idList->numIds()-1; i++) {
#ifndef EXCEPTIONS_DEFINED
        if (frame.getContext().getError().getErrorCode()!=skScriptError::NONE)
            break;
#endif
        idNode=idList->getId(i);
        name=idNode->getId();
        name=checkIndirectId(frame,name);
        //    trace("followIdList: %d: %s\n",i,(const char *)name);
        skRValue result;
        SAVE_VARIABLE(result);
        if (idNode->getExprs()==0) {
            if (idNode->getArrayIndex())
                extractFieldArrayValue(frame,object,name,idNode->getArrayIndex(),blank,result);
            else if (extractValue(frame,object,name,blank,result)==false)
                runtimeError(frame,skString::addStrings(s_FieldError,name.ptr(),s_cr));
        } else
            makeMethodCall(frame,object,name,idNode->getArrayIndex(),blank,idNode->getExprs(),result);
        object=result;
        RELEASE_VARIABLE(result);
    }
}
Ejemplo n.º 26
0
/**
 * Read attributes of a node.
 * @param initialArgs  Tokens on the line of the opening "(" of the node
 *                   but with leading whitespace and the opening "(" removed.
 * @param stream     The QTextStream from which to read following lines.
 * @return           Pointer to the created PetalNode or NULL on error.
 */
PetalNode *readAttributes(QStringList initialArgs, QTextStream& stream)
{
    methodName(QLatin1String("readAttributes"));
    if (initialArgs.count() == 0) {
        uError() << loc() << "initialArgs is empty";
        return NULL;
    }
    PetalNode::NodeType nt;
    QString type = shift(initialArgs);
    if (type == QLatin1String("object"))
        nt = PetalNode::nt_object;
    else if (type == QLatin1String("list"))
        nt = PetalNode::nt_list;
    else {
        uError() << loc() << "unknown node type " << type;
        return NULL;
    }
    PetalNode *node = new PetalNode(nt);
    bool seenClosing = checkClosing(initialArgs);
    node->setInitialArgs(initialArgs);
    if (seenClosing)
        return node;
    PetalNode::NameValueList attrs;
    QString line;
    while (!(line = stream.readLine()).isNull()) {
        linum++;
        line = line.trimmed();
        if (line.isEmpty())
            continue;
        QStringList tokens = scan(line);
        QString stringOrNodeOpener = shift(tokens);
        QString name;
        if (nt == PetalNode::nt_object && !stringOrNodeOpener.contains(QRegExp(QLatin1String("^[A-Za-z]")))) {
            uError() << loc() << "unexpected line " << line;
            delete node;
            return NULL;
        }
        PetalNode::StringOrNode value;
        if (nt == PetalNode::nt_object) {
            name = stringOrNodeOpener;
            if (tokens.count() == 0) {  // expect verbatim text to follow on subsequent lines
                value.string = collectVerbatimText(stream);
                PetalNode::NameValue attr(name, value);
                attrs.append(attr);
                if (nClosures) {
                    // Decrement nClosures exactly once, namely for the own scope.
                    // Each recursion of readAttributes() is only responsible for
                    // its own scope. I.e. each further scope closing is handled by
                    // an outer recursion in case of multiple closing parentheses.
                    nClosures--;
                    break;
                }
                continue;
            }
            stringOrNodeOpener = shift(tokens);
        } else if (stringOrNodeOpener != QLatin1String("(")) {
            value.string = stringOrNodeOpener;
            PetalNode::NameValue attr;
            attr.second = value;
            attrs.append(attr);
            if (tokens.count() && tokens.first() != QLatin1String(")")) {
                uDebug() << loc()
                    << "NYI - immediate list entry with more than one item";
            }
            if (checkClosing(tokens))
                break;
            continue;
        }
        if (stringOrNodeOpener == QLatin1String("(")) {
            QString nxt = tokens.first();
            if (isImmediateValue(nxt)) {
                value.string = extractImmediateValues(tokens);
            } else if (nxt == QLatin1String("value") || nxt.startsWith(QLatin1Char('"'))) {
                value.string = extractValue(tokens, stream);
            } else {
                value.node = readAttributes(tokens, stream);
                if (value.node == NULL) {
                    delete node;
                    return NULL;
                }
            }
            PetalNode::NameValue attr(name, value);
            attrs.append(attr);
            if (nClosures) {
                // Decrement nClosures exactly once, namely for the own scope.
                // Each recursion of readAttributes() is only responsible for
                // its own scope. I.e. each further scope closing is handled by
                // an outer recursion in case of multiple closing parentheses.
                nClosures--;
                break;
            }
        } else {
            value.string = stringOrNodeOpener;
            bool seenClosing = checkClosing(tokens);
            PetalNode::NameValue attr(name, value);
            attrs.append(attr);
            if (seenClosing) {
                break;
            }
        }
    }
    node->setAttributes(attrs);
    return node;
}
Ejemplo n.º 27
0
void NCDParser::launch()
{
  std::ifstream aLogFile;
  aLogFile.open(filename_);

  if(!aLogFile.is_open())
    ROS_FATAL("Could not open %s\n", filename_);

  int lineCounter = 0;
  std::string line;

  // **** skip first lines

  for (int i = 0; i < 210; i++)
  {
    getline(aLogFile, line);
    lineCounter++;
  }

  // **** iterate over rest of file

  while (getline(aLogFile, line))
  {
    lineCounter++;
    std::vector<std::string> tokens;
    tokenize(line, tokens, " ");

    // skip incomplete line
    if (tokens.size() < 4) continue;

    // skip log entries before start time
    if (strtod(tokens[0].c_str(), NULL) <= start_) continue;

    // stop if time is bigger than end point time
    if (strtod(tokens[0].c_str(), NULL) > end_ && end_ != -1)
    {
      std::cout << strtod(tokens[0].c_str(), NULL) << ", " << end_ << std::endl;
      ROS_INFO("Reached specified end time.");
      break;
    }

    // publish messages
    if      (tokens[1].compare("LMS_LASER_2D_LEFT") == 0)
      publishLaserMessage(tokens, leftLaserFrame_, leftLaserPublisher_);  
    else if (tokens[1].compare("LMS_LASER_2D_RIGHT") == 0)
      publishLaserMessage(tokens, rightLaserFrame_, rightLaserPublisher_);
    else if (tokens[1].compare("ODOMETRY_POSE") == 0)
      publishTfMessages(tokens);
    else
      continue;

    // wait before publishing next message

    double time = extractValue(tokens[3], "time=");

    if(lastTime_ == -1) lastTime_ = time; 
    else
    {
      ros::Duration d = (ros::Time(time) - ros::Time(lastTime_)) * ( 1.0 / rate_);
      lastTime_ = time;
      if (d.toNSec() > 0) d.sleep();
    }
  }
}
//---------------------------------------------------
skRValue skInterpreter::evaluate(skStackFrame& frame,skExprNode * n)
//---------------------------------------------------
{
    skRValue r;
    skString blank;
    SAVE_VARIABLE(r);
    skRValue item1;
    SAVE_VARIABLE(item1);
    skRValue item2;
    SAVE_VARIABLE(item2);
    switch(n->getType()) {
    case s_IdList: {
        skIdListNode * ids=(skIdListNode *)n;
        skIdNode * idNode=ids->getLastId();
        skString method_name;
        SAVE_VARIABLE(method_name);
        method_name=idNode->getId();
        if (ids->numIds()==1) {
            if (idNode->getExprs()==0)
                r=findValue(frame,method_name,idNode->getArrayIndex(),ids->getAttribute());
            else {
                skRValue caller;
                caller.assignObject(frame.getObject());
                makeMethodCall(frame,caller,method_name,idNode->getArrayIndex(),ids->getAttribute(),idNode->getExprs(),r);
            }
        } else {
            method_name=checkIndirectId(frame,method_name);
            skRValue robject;
            SAVE_VARIABLE(robject);
            followIdList(frame,ids,robject);
            if (idNode->getExprs()==0) {
                if (idNode->getArrayIndex()) {
                    skRValue array_field;
                    if (extractValue(frame,robject,method_name,blank,array_field))
                        extractArrayValue(frame,array_field,idNode->getArrayIndex(),ids->getAttribute(),r);
                    else
                        runtimeError(frame,skString::addStrings(s_FieldError,method_name.ptr(),s_cr));
                } else if (extractValue(frame,robject,method_name,ids->getAttribute(),r)==false)
                    runtimeError(frame,skString::addStrings(s_FieldError,method_name.ptr(),s_cr));
            } else
                makeMethodCall(frame,robject,method_name,idNode->getArrayIndex(),ids->getAttribute(),idNode->getExprs(),r);
            RELEASE_VARIABLE(robject);
        }
        RELEASE_VARIABLE(method_name);
        break;
    }
    case s_String:
        r=skRValue(((skLiteralNode *)n)->getString());
        break;
    case s_Integer:
        r=skRValue(((skLiteralNode *)n)->getInt());
        break;
    case s_Character:
        r=skRValue(((skLiteralNode *)n)->getChar());
        break;
#ifdef USE_FLOATING_POINT
    case s_Float:
        r=skRValue(((skLiteralNode *)n)->getFloat());
        break;
#endif
    default: {
        skOpNode * opNode=(skOpNode *)n;
        item1=evaluate(frame,opNode->getExpr1());
        int item1Type=item1.type();
        switch(n->getType()) {
        case s_Not:
            r=bool(!item1.boolValue());
            break;
        case s_And:
            r=bool(item1.boolValue() && evaluate(frame,opNode->getExpr2()).boolValue());
            break;
        case s_Or:
            r=bool(item1.boolValue() || evaluate(frame,opNode->getExpr2()).boolValue());
            break;
        case s_Equals:
            r=bool(item1 == evaluate(frame,opNode->getExpr2()));
            break;
        case s_NotEquals: {
            bool equals=item1 == evaluate(frame,opNode->getExpr2());
            if (equals)
                r=false;
            else
                r=true;
            break;
        }
        case s_Minus:
            if (item1Type==skRValue::T_Float)
                r=skRValue(-item1.floatValue());
            else
                r=skRValue((-item1.intValue()));
            break;
        case s_Concat:
            r=skRValue(skString::addStrings(item1.str(),evaluate(frame,opNode->getExpr2()).str()));
            break;
        default: {
            item2=evaluate(frame,opNode->getExpr2());
            int item2Type=item2.type();
            if (item1Type==skRValue::T_Int && item2Type==skRValue::T_Int) {
                // we can use integer arithmetic if both objects are integer
                int val1=item1.intValue();
                int val2=item2.intValue();
                switch(opNode->getType()) {
                case s_Plus:
                    r=skRValue(val1+val2);
                    break;
                case s_More:
                    r=bool(val1>val2);
                    break;
                case s_MoreEqual:
                    r=bool(val1>=val2);
                    break;
                case s_Less:
                    r=bool(val1<val2);
                    break;
                case s_LessEqual:
                    r=bool(val1<=val2);
                    break;
                case s_Subtract:
                    r=skRValue(val1-val2);
                    break;
                case s_Divide: {
                    long top=val1;
                    long bottom=val2;
                    if (bottom)
                        r=skRValue((int)(top/bottom));
                    else {
                        r=skRValue((int)1);
                        runtimeError(frame,skSTR("Divide by zero error"));
                    }
                    break;
                }
                case s_Mult:
                    r=skRValue(val1*val2);
                    break;
                case s_Mod:
                    r=skRValue(val1 % val2);
                    break;
                }
            } else {
                // in all other cases we using floating point
                float val1=item1.floatValue();
                float val2=item2.floatValue();
                switch(opNode->getType()) {
                case s_Plus:
                    r=skRValue(val1+val2);
                    break;
                case s_More:
                    r=bool(val1>val2);
                    break;
                case s_MoreEqual:
                    r=bool(val1>=val2);
                    break;
                case s_Less:
                    r=bool(val1<val2);
                    break;
                case s_LessEqual:
                    r=bool(val1<=val2);
                    break;
                case s_Subtract:
                    r=skRValue(val1-val2);
                    break;
                case s_Divide: {
                    double top=val1;
                    double bottom=val2;
                    if (bottom)
                        r=skRValue((float)(top/bottom));
                    else {
                        r=skRValue(1.0f);
                        runtimeError(frame,skSTR("Divide by zero error"));
                    }
                    break;
                }
                case s_Mult:
                    r=skRValue(val1*val2);
                    break;
                case s_Mod:
                    r=skRValue((int)((long)val1 % (long)val2));
                    break;
                }
            }
        }
        }
    }
    }
    RELEASE_VARIABLE(item2);
    RELEASE_VARIABLE(item1);
    RELEASE_VARIABLE(r);
    return r;
}
Ejemplo n.º 29
0
/* 
 *  ruleMatch
 * 
 *          p: packet data structure, same as the one found in snort.
 *    options: NULL terminated list of rule options
 *
 * Returns: 
 *    > 0 : match found
 *    = 0 : no match found
 *
 * Predefined constants: 
 *    (see sf_snort_plugin_api.h for more values)
 *    RULE_MATCH   -  if asn1 specifier is found within buffer 
 *    RULE_NOMATCH -  if asn1 specifier is not found within buffer 
 * 
 */
int ruleMatchInternal(SFSnortPacket *p, Rule* rule, u_int32_t optIndex, u_int8_t **cursor)
{
    u_int8_t *thisCursor = NULL, *startCursor = NULL;
    u_int8_t *tmpCursor = NULL;
    int retVal = RULE_NOMATCH;
    u_int32_t notFlag = 0;
    int thisType;
    ContentInfo *thisContentInfo = NULL;
    int startAdjust = 0;
    u_int32_t origFlags = 0;
    int32_t origOffset = 0;
    u_int32_t origDepth = 0;
    int continueLoop = 1;
    PCREInfo *thisPCREInfo = NULL;

    if (cursor)
        startCursor = thisCursor = *cursor;

    if (optIndex >= rule->numOptions || !rule->options[optIndex] )
        return RULE_NOMATCH;

    thisType = rule->options[optIndex]->optionType;

    /* Do some saving off of some info for recursion purposes */
    switch (thisType)
    {
        case OPTION_TYPE_CONTENT:
            thisContentInfo = rule->options[optIndex]->option_u.content;
            origFlags = thisContentInfo->flags;
            origDepth = thisContentInfo->depth;
            origOffset = thisContentInfo->offset;
            break;
        case OPTION_TYPE_PCRE:
            thisPCREInfo = rule->options[optIndex]->option_u.pcre;
            origFlags = thisPCREInfo->flags;
            break;
        default:
            /* Other checks should not need to check again like
             * PCRE & Content do.
             */
            break;
    }

    do
    {
        switch (thisType)
        {
        case OPTION_TYPE_CONTENT:
            retVal = contentMatch(p, rule->options[optIndex]->option_u.content, &thisCursor);
            notFlag = rule->options[optIndex]->option_u.content->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_PCRE:
            retVal = pcreMatch(p, rule->options[optIndex]->option_u.pcre, &thisCursor);
            notFlag = rule->options[optIndex]->option_u.pcre->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_FLOWBIT:
            retVal = processFlowbits(p, rule->options[optIndex]->option_u.flowBit);
            notFlag = rule->options[optIndex]->option_u.flowBit->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_BYTE_TEST:
            retVal = byteTest(p, rule->options[optIndex]->option_u.byte, thisCursor);
            notFlag = rule->options[optIndex]->option_u.byte->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_BYTE_JUMP:
            retVal = byteJump(p, rule->options[optIndex]->option_u.byte, &thisCursor);
            notFlag = rule->options[optIndex]->option_u.byte->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_FLOWFLAGS:
            retVal = checkFlow(p, rule->options[optIndex]->option_u.flowFlags);
            notFlag = rule->options[optIndex]->option_u.flowFlags->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_ASN1:
            retVal = detectAsn1(p, rule->options[optIndex]->option_u.asn1, thisCursor);
            notFlag = rule->options[optIndex]->option_u.asn1->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_CURSOR:
            retVal = checkCursor(p, rule->options[optIndex]->option_u.cursor, thisCursor);
            notFlag = rule->options[optIndex]->option_u.cursor->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_SET_CURSOR:
            retVal = setCursor(p, rule->options[optIndex]->option_u.cursor, &thisCursor);
            notFlag = rule->options[optIndex]->option_u.cursor->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_HDR_CHECK:
            retVal = checkHdrOpt(p, rule->options[optIndex]->option_u.hdrData);
            notFlag = rule->options[optIndex]->option_u.hdrData->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_BYTE_EXTRACT:
            retVal = extractValue(p, rule->options[optIndex]->option_u.byteExtract, thisCursor);
            notFlag = rule->options[optIndex]->option_u.byteExtract->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_LOOP:
            retVal = loopEval(p, rule->options[optIndex]->option_u.loop, &thisCursor);
            notFlag = rule->options[optIndex]->option_u.loop->flags & NOT_FLAG;
            break;
        case OPTION_TYPE_PREPROCESSOR:
            retVal = preprocOptionEval(p, rule->options[optIndex]->option_u.preprocOpt, &thisCursor);
            notFlag = rule->options[optIndex]->option_u.preprocOpt->flags & NOT_FLAG;
            break;
        }

        if ( notFlag )
        {
            if ((retVal <= RULE_NOMATCH))
            {
                /* Set this as a positive match -- a ! was specified. */
                retVal = RULE_MATCH;
            }
            else  /* Match */
            {
                retVal = RULE_NOMATCH;
            }
        }

        if (retVal > RULE_NOMATCH)
        {
            /* This one matched.  Depending on type, check the next one
             * either in a loop, or not, saving cursor temporarily.
             */
            if (optIndex < rule->numOptions -1) /* hehe, optIndex is 0 based */
            {
                int nestedRetVal;
                /* Here's where it gets tricky... */
                if (thisType == OPTION_TYPE_CONTENT)
                {
                    /* If this is a content option, we've found a match.
                     * Save off the end-point of the current match.
                     * Less the length of current match plus 1.
                     *
                     * This gives us the starting point to check for this
                     * content again if subsequent options fail.  That starting
                     * point is the byte AFTER the beginning of the current
                     * match.
                     */
                    if ((origFlags & CONTENT_RELATIVE) && startCursor)
                    {
                        /* relative content.
                         * need to adjust offset/depth as well
                         */
                        tmpCursor = thisCursor -
                            thisContentInfo->patternByteFormLength + thisContentInfo->incrementLength;

                        /* Start Adjust is the difference between the old
                         * starting point and the 'next' starting point. */
                        startAdjust = tmpCursor - startCursor;
                    }
                    else
                    {
                        /* non-relative content */
                        tmpCursor = thisCursor -
                            thisContentInfo->patternByteFormLength + thisContentInfo->incrementLength;
                    }
                }
                else if (thisType == OPTION_TYPE_PCRE)
                {
                    /* Start next search at end of current pattern */
                    /* XXX: Could miss something here if part of pattern
                     * repeats but not easy to tell with PCRE.
                     */
                    tmpCursor = thisCursor;
                }

                nestedRetVal = ruleMatchInternal(p, rule, optIndex+1, &thisCursor);
                if (nestedRetVal == RULE_MATCH)
                {
                    /* Cool, everyone after us matched, we're done with a match */
                    if (cursor)
                        *cursor = thisCursor;
                    break;
                }

                /* If Content or PCRE, look farther into the packet
                 * for another match. */
                if (((thisType == OPTION_TYPE_CONTENT) ||
                     (thisType == OPTION_TYPE_PCRE))
                     && !notFlag)
                {
                    /* Only try to find this content again if it is a
                     * positive match.
                     */

                    /* And only if the next option is relative */
                    if (!isRelativeOption(rule->options[optIndex+1]))
                    {
                        /* Match failed, next option is not relative. 
                         * We're done. */
                        retVal = nestedRetVal;
                        break;
                    }

                    switch (thisType)
                    {
                    case OPTION_TYPE_CONTENT:
                        if (origFlags & CONTENT_RELATIVE)
                        {
                            if ((int32_t)(origDepth - startAdjust) < (int32_t)thisContentInfo->patternByteFormLength)
                            {
                                /* Adjusted depth would be less than the content we're searching for?
                                 * we're done. */
                                retVal = nestedRetVal;
                                continueLoop = 0;
                            }
                            else
                            {
                                /* For contents that were already relative, adjust the offset & depth fields
                                 * from their original values.  Makes it easy to determine when we'll be out
                                 * of the original bounds, relative to the original cursor. */
                                thisContentInfo->offset = origOffset + startAdjust;
                                thisContentInfo->depth = origDepth - startAdjust;

                                /* And use the original cursor that was passed in */
                                thisCursor = startCursor;
                            }
                        }
                        else
                        {
                            thisContentInfo->flags |= CONTENT_RELATIVE;
                            /* For contents that were not already relative, we simply use the adjusted
                             * cursor.  Set thisCursor to tmpCursor as calculated above */
                            thisCursor = tmpCursor;
                        }
                        break;
                    case OPTION_TYPE_PCRE:
                        /* Doesn't matter if it was already relative,
                         * just make it relative anyway.
                         */
                        thisPCREInfo->flags |= CONTENT_RELATIVE;
                        /* For PCREs that were not already relative, we use the cursor
                         * that was returned at the end of the pattern to start searching
                         * again. */
                        thisCursor = tmpCursor;
                        break;
                    }
                    continue;
                }


                /* Only need to search again when this is a
                 * content option.  If its not, we're done. */
                if (nestedRetVal <= RULE_NOMATCH)
                {
                    /* Handle the case when an error is propigated
                     * via nestedRetVal.
                     */
                    retVal = RULE_NOMATCH;
                }
                break;
            }
            else
            {
                /* Cool, nobody after us, we're done with a match */
                if (cursor)
                    *cursor = thisCursor;
                break;
            }
        }
        else
        {
            /* No match, get outta dodge */
            break;
        }
    } while (continueLoop);
    /* Keep looping until we break or serialized content checks returns no match. */

    /* Reset the flags for this content in case we added the
     * relative flag above.
     */
    if (thisContentInfo)
    {
        thisContentInfo->flags = origFlags;
        thisContentInfo->offset = origOffset;
        thisContentInfo->depth = origDepth;
    }
    if (thisPCREInfo)
    {
        thisPCREInfo->flags = origFlags;
    }

    return retVal;
}
Ejemplo n.º 30
0
void Expression::tokenize()
{
	struct Token tempToken;
	char c;
	while((c=expression[expressionIndex])!='\0') { //isFunction(*expression);
		if(isDigit(c)) { // if first char is digit
			char temp[20];
			unsigned int count = 0, dotcount = 0;
			while(isDigit(c) or c=='.') {
                if(c=='.')dotcount++;
                if(dotcount>1) throw(parse); // error, more than 1 dots
				temp[count++] = c;
				c = expression[++expressionIndex];
			}
			temp[count] = '\0';
			tempToken.numVal = extractValue(temp);
			tempToken.type = VALUE;

			tokens.push_back(tempToken); // store the token
		}

		else if(isOperator(c)) { // symbol is an operator
            if(isOperator(expression[expressionIndex+1]))throw(parse); // error, two operators at same place
			if((expressionIndex==0 or expression[expressionIndex-1]=='(') and c=='-') c='#';
			char temp[2];
			temp[0]= c;
			temp[1] = '\0';

			strcpy(tempToken.str, temp);
			tempToken.type = OPERATOR;

			tokens.push_back(tempToken); // store the token

			c = expression[++expressionIndex];
		}

		else if(isVariable(c) or isConstant(c)) { // symbol is a variable or the constant
            char d = expression[expressionIndex+1];
            if(isVariable(d) or isConstant(d)) throw parse;
            if(c=='z')throw parse;
            char temp[2];
			temp[0]= c;
			temp[1] = '\0';

			strcpy(tempToken.str, temp);
			if(isVariable(c)) tempToken.type = VARIABLE;
			if(isConstant(c)) tempToken.type = CONSTANT;

			tokens.push_back(tempToken); // store the token

			c = expression[++expressionIndex];
		}

		else if (isFunction(expression+expressionIndex)) {
			char t2[3], t3[4], t4[5];
			int i = expressionIndex;
			char *tempc = expression;
			t2[0]=tempc[i]; t2[1]=tempc[i+1];t2[2]='\0';
			t3[0]=tempc[i];t3[1]=tempc[i+1];t3[2]=tempc[i+2];t3[3]='\0';
			t4[0]=tempc[i];t4[1]=tempc[i+1];t4[2]=tempc[i+2];t4[3]=tempc[i+3];t4[4]='\0';
			for(int x = 0;x<numFunctions; x++) {
				if(strcmp(t4, functions[x])==0) { strcpy(tempToken.str, functions[x]); expressionIndex+=4; break;}
				if(strcmp(t2, functions[x])==0) { strcpy(tempToken.str, functions[x]); expressionIndex+=2; break;}
				if(strcmp(t3, functions[x])==0) { strcpy(tempToken.str, functions[x]); expressionIndex+=3; break;}
			}
			tempToken.type = FUNCTION;

			tokens.push_back(tempToken); // store the token

			c = expression[expressionIndex];
		}

		else if (c=='(') {
			tempToken.type = LEFT_PARENTHESIS;
			char temp[2];
			temp[0] = c; temp[1]= '\0';

			strcpy(tempToken.str, temp);
			tokens.push_back(tempToken); // store the token

			expressionIndex++;
			c = expression[expressionIndex];
		}

		else if (c==')') {
			tempToken.type = RIGHT_PARENTHESIS;
			char temp[2];
			temp[0] = c; temp[1]= '\0';

			strcpy(tempToken.str, temp);
			tokens.push_back(tempToken); // store the token

			expressionIndex++;
			c = expression[expressionIndex];
		}

		else if (c==' ') { // ignore the spaces
			++expressionIndex;
			c = expression[expressionIndex];
		}

		else {
            throw (token);
			++expressionIndex;
			c= expression[expressionIndex];
		} // unrecognized token;
	}

}