}
/**
* @return true
* @see ClassifierFacade
*/
public boolean isClassifierFacadeMetaType()
{
return true;
}
/**
* @return true
* @see GeneralizableElementFacade
*/
public boolean isGeneralizableElementFacadeMetaType()
{
return true;
}
/**
* @return true
* @see ModelElementFacade
*/
public boolean isModelElementFacadeMetaType()
{
return true;
}
// ----------- delegates to ClassifierFacade ------------
/**
* Return the attribute which name matches the parameter
* @see ClassifierFacade#findAttribute(String name)
*/
public AttributeFacade findAttribute(String name)
{
return this.getSuperClassifierFacade().findAttribute(name);
}
/**
* Those abstraction dependencies for which this classifier is the client.
* @see ClassifierFacade#getAbstractions()
*/
public Collection<ClassifierFacade> getAbstractions()
{
return this.getSuperClassifierFacade().getAbstractions();
}
/**
* Lists all classes associated to this one and any ancestor classes (through generalization).
* There will be no duplicates. The order of the elements is predictable.
* @see ClassifierFacade#getAllAssociatedClasses()
*/
public Collection<ClassifierFacade> getAllAssociatedClasses()
{
return this.getSuperClassifierFacade().getAllAssociatedClasses();
}
/**
* A collection containing all 'properties' of the classifier and its ancestors. Properties are
* any attributes and navigable connecting association ends.
* @see ClassifierFacade#getAllProperties()
*/
public Collection<ModelElementFacade> getAllProperties()
{
return this.getSuperClassifierFacade().getAllProperties();
}
/**
* A collection containing all required and/or read-only 'properties' of the classifier and its
* ancestors. Properties are any attributes and navigable connecting association ends.
* @see ClassifierFacade#getAllRequiredConstructorParameters()
*/
public Collection<ModelElementFacade> getAllRequiredConstructorParameters()
{
return this.getSuperClassifierFacade().getAllRequiredConstructorParameters();
}
/**
* Gets the array type for this classifier. If this classifier already represents an array, it
* just returns itself.
* @see ClassifierFacade#getArray()
*/
public ClassifierFacade getArray()
{
return this.getSuperClassifierFacade().getArray();
}
/**
* The name of the classifier as an array.
* @see ClassifierFacade#getArrayName()
*/
public String getArrayName()
{
return this.getSuperClassifierFacade().getArrayName();
}
/**
* Lists the classes associated to this one, there is no repitition of classes. The order of the
* elements is predictable.
* @see ClassifierFacade#getAssociatedClasses()
*/
public Collection<ClassifierFacade> getAssociatedClasses()
{
return this.getSuperClassifierFacade().getAssociatedClasses();
}
/**
* Gets the association ends belonging to a classifier.
* @see ClassifierFacade#getAssociationEnds()
*/
public List<AssociationEndFacade> getAssociationEnds()
{
return this.getSuperClassifierFacade().getAssociationEnds();
}
/**
* Gets the attributes that belong to the classifier.
* @see ClassifierFacade#getAttributes()
*/
public List<AttributeFacade> getAttributes()
{
return this.getSuperClassifierFacade().getAttributes();
}
/**
* Gets all attributes for the classifier and if 'follow' is true goes up the inheritance
* hierarchy and gets the attributes from the super classes as well.
* @see ClassifierFacade#getAttributes(boolean follow)
*/
public List<AttributeFacade> getAttributes(boolean follow)
{
return this.getSuperClassifierFacade().getAttributes(follow);
}
/**
* The fully qualified name of the classifier as an array.
* @see ClassifierFacade#getFullyQualifiedArrayName()
*/
public String getFullyQualifiedArrayName()
{
return this.getSuperClassifierFacade().getFullyQualifiedArrayName();
}
/**
* Returns all those operations that could be implemented at this classifier's level. This means
* the operations owned by this classifier as well as any realized interface's operations
* (recursively) in case this classifier itself is not already an interface, or generalized when
* this classifier is an interface.
* @see ClassifierFacade#getImplementationOperations()
*/
public Collection<OperationFacade> getImplementationOperations()
{
return this.getSuperClassifierFacade().getImplementationOperations();
}
/**
* A comma separated list of the fully qualified names of all implemented interfaces.
* @see ClassifierFacade#getImplementedInterfaceList()
*/
public String getImplementedInterfaceList()
{
return this.getSuperClassifierFacade().getImplementedInterfaceList();
}
/**
* Those attributes that are scoped to an instance of this class.
* @see ClassifierFacade#getInstanceAttributes()
*/
public Collection<AttributeFacade> getInstanceAttributes()
{
return this.getSuperClassifierFacade().getInstanceAttributes();
}
/**
* Those operations that are scoped to an instance of this class.
* @see ClassifierFacade#getInstanceOperations()
*/
public List<OperationFacade> getInstanceOperations()
{
return this.getSuperClassifierFacade().getInstanceOperations();
}
/**
* Those interfaces that are abstractions of this classifier, this basically means this
* classifier realizes them.
* @see ClassifierFacade#getInterfaceAbstractions()
*/
public Collection<ClassifierFacade> getInterfaceAbstractions()
{
return this.getSuperClassifierFacade().getInterfaceAbstractions();
}
/**
* A String representing a new Constructor declaration for this classifier type to be used in a
* Java environment.
* @see ClassifierFacade#getJavaNewString()
*/
public String getJavaNewString()
{
return this.getSuperClassifierFacade().getJavaNewString();
}
/**
* A String representing the null-value for this classifier type to be used in a Java
* environment.
* @see ClassifierFacade#getJavaNullString()
*/
public String getJavaNullString()
{
return this.getSuperClassifierFacade().getJavaNullString();
}
/**
* The other ends of this classifier's association ends which are navigable.
* @see ClassifierFacade#getNavigableConnectingEnds()
*/
public Collection<AssociationEndFacade> getNavigableConnectingEnds()
{
return this.getSuperClassifierFacade().getNavigableConnectingEnds();
}
/**
* Get the other ends of this classifier's association ends which are navigable and if 'follow'
* is true goes up the inheritance hierarchy and gets the super association ends as well.
* @see ClassifierFacade#getNavigableConnectingEnds(boolean follow)
*/
public List<AssociationEndFacade> getNavigableConnectingEnds(boolean follow)
{
return this.getSuperClassifierFacade().getNavigableConnectingEnds(follow);
}
/**
* Assuming that the classifier is an array, this will return the non array type of the
* classifier from
* the model. If the classifier is NOT an array, it will just return itself.
* @see ClassifierFacade#getNonArray()
*/
public ClassifierFacade getNonArray()
{
return this.getSuperClassifierFacade().getNonArray();
}
/**
* The attributes from this classifier in the form of an operation call (this example would be
* in Java): '(String attributeOne, String attributeTwo). If there were no attributes on the
* classifier, the result would be an empty '()'.
* @see ClassifierFacade#getOperationCallFromAttributes()
*/
public String getOperationCallFromAttributes()
{
return this.getSuperClassifierFacade().getOperationCallFromAttributes();
}
/**
* The operations owned by this classifier.
* @see ClassifierFacade#getOperations()
*/
public List<OperationFacade> getOperations()
{
return this.getSuperClassifierFacade().getOperations();
}
/**
* A collection containing all 'properties' of the classifier. Properties are any attributes
* and navigable connecting association ends.
* @see ClassifierFacade#getProperties()
*/
public List<ModelElementFacade> getProperties()
{
return this.getSuperClassifierFacade().getProperties();
}
/**
* Gets all properties (attributes and navigable association ends) for the classifier and if
* 'follow' is true goes up the inheritance hierarchy and gets the properties from the super
* classes as well.
* @see ClassifierFacade#getProperties(boolean follow)
*/
public List getProperties(boolean follow)
{
return this.getSuperClassifierFacade().getProperties(follow);
}
/**
* A collection containing all required and/or read-only 'properties' of the classifier.
* Properties are any attributes and navigable connecting association ends.
* @see ClassifierFacade#getRequiredConstructorParameters()
*/
public Collection<ModelElementFacade> getRequiredConstructorParameters()
{
return this.getSuperClassifierFacade().getRequiredConstructorParameters();
}
/**
* Returns the serial version UID of the underlying model element.
* @see ClassifierFacade#getSerialVersionUID()
*/
public long getSerialVersionUID()
{
return this.getSuperClassifierFacade().getSerialVersionUID();
}
/**
* Those attributes that are scoped to the definition of this class.
* @see ClassifierFacade#getStaticAttributes()
*/
public Collection<AttributeFacade> getStaticAttributes()
{
return this.getSuperClassifierFacade().getStaticAttributes();
}
/**
* Those operations that are scoped to the definition of this class.
* @see ClassifierFacade#getStaticOperations()
*/
public List<OperationFacade> getStaticOperations()
{
return this.getSuperClassifierFacade().getStaticOperations();
}
/**
* This class' superclass, returns the generalization if it is a ClassifierFacade, null
* otherwise.
* @see ClassifierFacade#getSuperClass()
*/
public ClassifierFacade getSuperClass()
{
return this.getSuperClassifierFacade().getSuperClass();
}
/**
* The wrapper name for this classifier if a mapped type has a defined wrapper class (ie. 'long'
* maps to 'Long'). If the classifier doesn't have a wrapper defined for it, this method will
* return a null. Note that wrapper mappings must be defined for the namespace by defining the
* 'wrapperMappingsUri', this property must point to the location of the mappings file which
* maps the primitives to wrapper types.
* @see ClassifierFacade#getWrapperName()
*/
public String getWrapperName()
{
return this.getSuperClassifierFacade().getWrapperName();
}
/**
* Indicates if this classifier is 'abstract'.
* @see ClassifierFacade#isAbstract()
*/
public boolean isAbstract()
{
return this.getSuperClassifierFacade().isAbstract();
}
/**
* True if this classifier represents an array type. False otherwise.
* @see ClassifierFacade#isArrayType()
*/
public boolean isArrayType()
{
return this.getSuperClassifierFacade().isArrayType();
}
/**
* True if the ClassifierFacade is an AssociationClass.
* @see ClassifierFacade#isAssociationClass()
*/
public boolean isAssociationClass()
{
return this.getSuperClassifierFacade().isAssociationClass();
}
/**
* Returns true if this type represents a Blob type.
* @see ClassifierFacade#isBlobType()
*/
public boolean isBlobType()
{
return this.getSuperClassifierFacade().isBlobType();
}
/**
* Indicates if this type represents a boolean type or not.
* @see ClassifierFacade#isBooleanType()
*/
public boolean isBooleanType()
{
return this.getSuperClassifierFacade().isBooleanType();
}
/**
* Indicates if this type represents a char, Character, or java.lang.Character type or not.
* @see ClassifierFacade#isCharacterType()
*/
public boolean isCharacterType()
{
return this.getSuperClassifierFacade().isCharacterType();
}
/**
* Returns true if this type represents a Clob type.
* @see ClassifierFacade#isClobType()
*/
public boolean isClobType()
{
return this.getSuperClassifierFacade().isClobType();
}
/**
* True if this classifier represents a collection type. False otherwise.
* @see ClassifierFacade#isCollectionType()
*/
public boolean isCollectionType()
{
return this.getSuperClassifierFacade().isCollectionType();
}
/**
* True/false depending on whether or not this classifier represents a datatype. A data type is
* a type whose instances are identified only by their value. A data type may contain attributes
* to support the modeling of structured data types.
* @see ClassifierFacade#isDataType()
*/
public boolean isDataType()
{
return this.getSuperClassifierFacade().isDataType();
}
/**
* True when this classifier is a date type.
* @see ClassifierFacade#isDateType()
*/
public boolean isDateType()
{
return this.getSuperClassifierFacade().isDateType();
}
/**
* Indicates if this type represents a Double type or not.
* @see ClassifierFacade#isDoubleType()
*/
public boolean isDoubleType()
{
return this.getSuperClassifierFacade().isDoubleType();
}
/**
* Indicates whether or not this classifier represents an "EmbeddedValue'.
* @see ClassifierFacade#isEmbeddedValue()
*/
public boolean isEmbeddedValue()
{
return this.getSuperClassifierFacade().isEmbeddedValue();
}
/**
* True if this classifier is in fact marked as an enumeration.
* @see ClassifierFacade#isEnumeration()
*/
public boolean isEnumeration()
{
return this.getSuperClassifierFacade().isEnumeration();
}
/**
* Returns true if this type represents a 'file' type.
* @see ClassifierFacade#isFileType()
*/
public boolean isFileType()
{
return this.getSuperClassifierFacade().isFileType();
}
/**
* Indicates if this type represents a Float type or not.
* @see ClassifierFacade#isFloatType()
*/
public boolean isFloatType()
{
return this.getSuperClassifierFacade().isFloatType();
}
/**
* Indicates if this type represents an int or Integer or java.lang.Integer type or not.
* @see ClassifierFacade#isIntegerType()
*/
public boolean isIntegerType()
{
return this.getSuperClassifierFacade().isIntegerType();
}
/**
* True/false depending on whether or not this Classifier represents an interface.
* @see ClassifierFacade#isInterface()
*/
public boolean isInterface()
{
return this.getSuperClassifierFacade().isInterface();
}
/**
* True if this classifier cannot be extended and represent a leaf in the inheritance tree.
* @see ClassifierFacade#isLeaf()
*/
public boolean isLeaf()
{
return this.getSuperClassifierFacade().isLeaf();
}
/**
* True if this classifier represents a list type. False otherwise.
* @see ClassifierFacade#isListType()
*/
public boolean isListType()
{
return this.getSuperClassifierFacade().isListType();
}
/**
* Indicates if this type represents a Long type or not.
* @see ClassifierFacade#isLongType()
*/
public boolean isLongType()
{
return this.getSuperClassifierFacade().isLongType();
}
/**
* Indicates whether or not this classifier represents a Map type.
* @see ClassifierFacade#isMapType()
*/
public boolean isMapType()
{
return this.getSuperClassifierFacade().isMapType();
}
/**
* Indicates whether or not this classifier represents a primitive type.
* @see ClassifierFacade#isPrimitive()
*/
public boolean isPrimitive()
{
return this.getSuperClassifierFacade().isPrimitive();
}
/**
* True if this classifier represents a set type. False otherwise.
* @see ClassifierFacade#isSetType()
*/
public boolean isSetType()
{
return this.getSuperClassifierFacade().isSetType();
}
/**
* Indicates whether or not this classifier represents a string type.
* @see ClassifierFacade#isStringType()
*/
public boolean isStringType()
{
return this.getSuperClassifierFacade().isStringType();
}
/**
* Indicates whether or not this classifier represents a time type.
* @see ClassifierFacade#isTimeType()
*/
public boolean isTimeType()
{
return this.getSuperClassifierFacade().isTimeType();
}
/**
* Returns true if this type is a wrapped primitive type.
* @see ClassifierFacade#isWrappedPrimitive()
*/
public boolean isWrappedPrimitive()
{
return this.getSuperClassifierFacade().isWrappedPrimitive();
}
/**
* Finds the tagged value optional searching the entire inheritance hierarchy if 'follow' is set
* to true.
* @see GeneralizableElementFacade#findTaggedValue(String tagName, boolean follow)
*/
public Object findTaggedValue(String tagName, boolean follow)
{
return this.getSuperClassifierFacade().findTaggedValue(tagName, follow);
}
/**
* All generalizations for this generalizable element, goes up the inheritance tree.
* @see GeneralizableElementFacade#getAllGeneralizations()
*/
public Collection<GeneralizableElementFacade> getAllGeneralizations()
{
return this.getSuperClassifierFacade().getAllGeneralizations();
}
/**
* All specializations (travels down the inheritance hierarchy).
* @see GeneralizableElementFacade#getAllSpecializations()
*/
public Collection<GeneralizableElementFacade> getAllSpecializations()
{
return this.getSuperClassifierFacade().getAllSpecializations();
}
/**
* Gets the direct generalization for this generalizable element.
* @see GeneralizableElementFacade#getGeneralization()
*/
public GeneralizableElementFacade getGeneralization()
{
return this.getSuperClassifierFacade().getGeneralization();
}
/**
* Gets the actual links that this generalization element is part of (it plays either the
* specialization or generalization).
* @see GeneralizableElementFacade#getGeneralizationLinks()
*/
public Collection<GeneralizationFacade> getGeneralizationLinks()
{
return this.getSuperClassifierFacade().getGeneralizationLinks();
}
/**
* A comma separated list of the fully qualified names of all generalizations.
* @see GeneralizableElementFacade#getGeneralizationList()
*/
public String getGeneralizationList()
{
return this.getSuperClassifierFacade().getGeneralizationList();
}
/**
* The element found when you recursively follow the generalization path up to the root. If an
* element has no generalization itself will be considered the root.
* @see GeneralizableElementFacade#getGeneralizationRoot()
*/
public GeneralizableElementFacade getGeneralizationRoot()
{
return this.getSuperClassifierFacade().getGeneralizationRoot();
}
/**
* Return all generalizations (ancestors) from this generalizable element.
* @see GeneralizableElementFacade#getGeneralizations()
*/
public Collection<GeneralizableElementFacade> getGeneralizations()
{
return this.getSuperClassifierFacade().getGeneralizations();
}
/**
* Gets the direct specializations (i.e. sub elements) for this generalizatble element.
* @see GeneralizableElementFacade#getSpecializations()
*/
public Collection<GeneralizableElementFacade> getSpecializations()
{
return this.getSuperClassifierFacade().getSpecializations();
}
/**
* Copies all tagged values from the given ModelElementFacade to this model element facade.
* @see ModelElementFacade#copyTaggedValues(ModelElementFacade element)
*/
public void copyTaggedValues(ModelElementFacade element)
{
this.getSuperClassifierFacade().copyTaggedValues(element);
}
/**
* Finds the tagged value with the specified 'tagName'. In case there are more values the first
* one found will be returned.
* @see ModelElementFacade#findTaggedValue(String tagName)
*/
public Object findTaggedValue(String tagName)
{
return this.getSuperClassifierFacade().findTaggedValue(tagName);
}
/**
* Returns all the values for the tagged value with the specified name. The returned collection
* will contains only String instances, or will be empty. Never null.
* @see ModelElementFacade#findTaggedValues(String tagName)
*/
public Collection<Object> findTaggedValues(String tagName)
{
return this.getSuperClassifierFacade().findTaggedValues(tagName);
}
/**
* Returns the fully qualified name of the model element. The fully qualified name includes
* complete package qualified name of the underlying model element. The templates parameter will
* be replaced by the correct one given the binding relation of the parameter to this element.
* @see ModelElementFacade#getBindedFullyQualifiedName(ModelElementFacade bindedElement)
*/
public String getBindedFullyQualifiedName(ModelElementFacade bindedElement)
{
return this.getSuperClassifierFacade().getBindedFullyQualifiedName(bindedElement);
}
/**
* Gets all constraints belonging to the model element.
* @see ModelElementFacade#getConstraints()
*/
public Collection<ConstraintFacade> getConstraints()
{
return this.getSuperClassifierFacade().getConstraints();
}
/**
* Returns the constraints of the argument kind that have been placed onto this model. Typical
* kinds are "inv", "pre" and "post". Other kinds are possible.
* @see ModelElementFacade#getConstraints(String kind)
*/
public Collection<ConstraintFacade> getConstraints(String kind)
{
return this.getSuperClassifierFacade().getConstraints(kind);
}
/**
* Gets the documentation for the model element, The indent argument is prefixed to each line.
* By default this method wraps lines after 64 characters.
* This method is equivalent to <code>getDocumentation(indent, 64)</code>.
* @see ModelElementFacade#getDocumentation(String indent)
*/
public String getDocumentation(String indent)
{
return this.getSuperClassifierFacade().getDocumentation(indent);
}
/**
* This method returns the documentation for this model element, with the lines wrapped after
* the specified number of characters, values of less than 1 will indicate no line wrapping is
* required. By default paragraphs are returned as HTML.
* This method is equivalent to <code>getDocumentation(indent, lineLength, true)</code>.
* @see ModelElementFacade#getDocumentation(String indent, int lineLength)
*/
public String getDocumentation(String indent, int lineLength)
{
return this.getSuperClassifierFacade().getDocumentation(indent, lineLength);
}
/**
* This method returns the documentation for this model element, with the lines wrapped after
* the specified number of characters, values of less than 1 will indicate no line wrapping is
* required. HTML style determines if HTML Escaping is applied.
* @see ModelElementFacade#getDocumentation(String indent, int lineLength, boolean htmlStyle)
*/
public String getDocumentation(String indent, int lineLength, boolean htmlStyle)
{
return this.getSuperClassifierFacade().getDocumentation(indent, lineLength, htmlStyle);
}
/**
* The fully qualified name of this model element.
* @see ModelElementFacade#getFullyQualifiedName()
*/
public String getFullyQualifiedName()
{
return this.getSuperClassifierFacade().getFullyQualifiedName();
}
/**
* Returns the fully qualified name of the model element. The fully qualified name includes
* complete package qualified name of the underlying model element. If modelName is true, then
* the original name of the model element (the name contained within the model) will be the name
* returned, otherwise a name from a language mapping will be returned.
* @see ModelElementFacade#getFullyQualifiedName(boolean modelName)
*/
public String getFullyQualifiedName(boolean modelName)
{
return this.getSuperClassifierFacade().getFullyQualifiedName(modelName);
}
/**
* Returns the fully qualified name as a path, the returned value always starts with out a slash
* '/'.
* @see ModelElementFacade#getFullyQualifiedNamePath()
*/
public String getFullyQualifiedNamePath()
{
return this.getSuperClassifierFacade().getFullyQualifiedNamePath();
}
/**
* Gets the unique identifier of the underlying model element.
* @see ModelElementFacade#getId()
*/
public String getId()
{
return this.getSuperClassifierFacade().getId();
}
/**
* UML2: Retrieves the keywords for this element. Used to modify implementation properties which
* are not represented by other properties, i.e. native, transient, volatile, synchronized,
* (added annotations) override, deprecated. Can also be used to suppress compiler warnings:
* (added annotations) unchecked, fallthrough, path, serial, finally, all. Annotations require
* JDK5 compiler level.
* @see ModelElementFacade#getKeywords()
*/
public Collection<String> getKeywords()
{
return this.getSuperClassifierFacade().getKeywords();
}
/**
* UML2: Retrieves a localized label for this named element.
* @see ModelElementFacade#getLabel()
*/
public String getLabel()
{
return this.getSuperClassifierFacade().getLabel();
}
/**
* The language mappings that have been set for this model element.
* @see ModelElementFacade#getLanguageMappings()
*/
public TypeMappings getLanguageMappings()
{
return this.getSuperClassifierFacade().getLanguageMappings();
}
/**
* Return the model containing this model element (multiple models may be loaded and processed
* at the same time).
* @see ModelElementFacade#getModel()
*/
public ModelFacade getModel()
{
return this.getSuperClassifierFacade().getModel();
}
/**
* The name of the model element.
* @see ModelElementFacade#getName()
*/
public String getName()
{
return this.getSuperClassifierFacade().getName();
}
/**
* Gets the package to which this model element belongs.
* @see ModelElementFacade#getPackage()
*/
public ModelElementFacade getPackage()
{
return this.getSuperClassifierFacade().getPackage();
}
/**
* The name of this model element's package.
* @see ModelElementFacade#getPackageName()
*/
public String getPackageName()
{
return this.getSuperClassifierFacade().getPackageName();
}
/**
* Gets the package name (optionally providing the ability to retrieve the model name and not
* the mapped name).
* @see ModelElementFacade#getPackageName(boolean modelName)
*/
public String getPackageName(boolean modelName)
{
return this.getSuperClassifierFacade().getPackageName(modelName);
}
/**
* Returns the package as a path, the returned value always starts with out a slash '/'.
* @see ModelElementFacade#getPackagePath()
*/
public String getPackagePath()
{
return this.getSuperClassifierFacade().getPackagePath();
}
/**
* UML2: Returns the value of the 'Qualified Name' attribute. A name which allows the
* NamedElement to be identified within a hierarchy of nested Namespaces. It is constructed from
* the names of the containing namespaces starting at the root of the hierarchy and ending with
* the name of the NamedElement itself.
* @see ModelElementFacade#getQualifiedName()
*/
public String getQualifiedName()
{
return this.getSuperClassifierFacade().getQualifiedName();
}
/**
* Gets the root package for the model element.
* @see ModelElementFacade#getRootPackage()
*/
public PackageFacade getRootPackage()
{
return this.getSuperClassifierFacade().getRootPackage();
}
/**
* Gets the dependencies for which this model element is the source.
* @see ModelElementFacade#getSourceDependencies()
*/
public Collection<DependencyFacade> getSourceDependencies()
{
return this.getSuperClassifierFacade().getSourceDependencies();
}
/**
* If this model element is the context of an activity graph, this represents that activity
* graph.
* @see ModelElementFacade#getStateMachineContext()
*/
public StateMachineFacade getStateMachineContext()
{
return this.getSuperClassifierFacade().getStateMachineContext();
}
/**
* The collection of ALL stereotype names for this model element.
* @see ModelElementFacade#getStereotypeNames()
*/
public Collection<String> getStereotypeNames()
{
return this.getSuperClassifierFacade().getStereotypeNames();
}
/**
* Gets all stereotypes for this model element.
* @see ModelElementFacade#getStereotypes()
*/
public Collection<StereotypeFacade> getStereotypes()
{
return this.getSuperClassifierFacade().getStereotypes();
}
/**
* Return the TaggedValues associated with this model element, under all stereotypes.
* @see ModelElementFacade#getTaggedValues()
*/
public Collection<TaggedValueFacade> getTaggedValues()
{
return this.getSuperClassifierFacade().getTaggedValues();
}
/**
* Gets the dependencies for which this model element is the target.
* @see ModelElementFacade#getTargetDependencies()
*/
public Collection<DependencyFacade> getTargetDependencies()
{
return this.getSuperClassifierFacade().getTargetDependencies();
}
/**
* Get the template parameter for this model element having the parameterName
* @see ModelElementFacade#getTemplateParameter(String parameterName)
*/
public Object getTemplateParameter(String parameterName)
{
return this.getSuperClassifierFacade().getTemplateParameter(parameterName);
}
/**
* Get the template parameters for this model element
* @see ModelElementFacade#getTemplateParameters()
*/
public Collection<TemplateParameterFacade> getTemplateParameters()
{
return this.getSuperClassifierFacade().getTemplateParameters();
}
/**
* The visibility (i.e. public, private, protected or package) of the model element, will
* attempt a lookup for these values in the language mappings (if any).
* @see ModelElementFacade#getVisibility()
*/
public String getVisibility()
{
return this.getSuperClassifierFacade().getVisibility();
}
/**
* Returns true if the model element has the exact stereotype (meaning no stereotype inheritance
* is taken into account when searching for the stereotype), false otherwise.
* @see ModelElementFacade#hasExactStereotype(String stereotypeName)
*/
public boolean hasExactStereotype(String stereotypeName)
{
return this.getSuperClassifierFacade().hasExactStereotype(stereotypeName);
}
/**
* Does the UML Element contain the named Keyword? Keywords can be separated by space, comma,
* pipe, semicolon, or << >>
* @see ModelElementFacade#hasKeyword(String keywordName)
*/
public boolean hasKeyword(String keywordName)
{
return this.getSuperClassifierFacade().hasKeyword(keywordName);
}
/**
* Returns true if the model element has the specified stereotype. If the stereotype itself
* does not match, then a search will be made up the stereotype inheritance hierarchy, and if
* one of the stereotype's ancestors has a matching name this method will return true, false
* otherwise.
* For example, if we have a certain stereotype called <<exception>> and a model element has a
* stereotype called <<applicationException>> which extends <<exception>>, when calling this
* method with 'stereotypeName' defined as 'exception' the method would return true since
* <<applicationException>> inherits from <<exception>>. If you want to check if the model
* element has the exact stereotype, then use the method 'hasExactStereotype' instead.
* @see ModelElementFacade#hasStereotype(String stereotypeName)
*/
public boolean hasStereotype(String stereotypeName)
{
return this.getSuperClassifierFacade().hasStereotype(stereotypeName);
}
/**
* True if there are target dependencies from this element that are instances of BindingFacade.
* Deprecated in UML2: Use TemplateBinding parameters instead of dependencies.
* @see ModelElementFacade#isBindingDependenciesPresent()
*/
public boolean isBindingDependenciesPresent()
{
return this.getSuperClassifierFacade().isBindingDependenciesPresent();
}
/**
* Indicates if any constraints are present on this model element.
* @see ModelElementFacade#isConstraintsPresent()
*/
public boolean isConstraintsPresent()
{
return this.getSuperClassifierFacade().isConstraintsPresent();
}
/**
* Indicates if any documentation is present on this model element.
* @see ModelElementFacade#isDocumentationPresent()
*/
public boolean isDocumentationPresent()
{
return this.getSuperClassifierFacade().isDocumentationPresent();
}
/**
* True if this element name is a reserved word in Java, C#, ANSI or ISO C, C++, JavaScript.
* @see ModelElementFacade#isReservedWord()
*/
public boolean isReservedWord()
{
return this.getSuperClassifierFacade().isReservedWord();
}
/**
* True is there are template parameters on this model element. For UML2, applies to Class,
* Operation, Property, and Parameter.
* @see ModelElementFacade#isTemplateParametersPresent()
*/
public boolean isTemplateParametersPresent()
{
return this.getSuperClassifierFacade().isTemplateParametersPresent();
}
/**
* True if this element name is a valid identifier name in Java, C#, ANSI or ISO C, C++,
* JavaScript. Contains no spaces, special characters etc. Constraint always applied on
* Enumerations and Interfaces, optionally applies on other model elements.
* @see ModelElementFacade#isValidIdentifierName()
*/
public boolean isValidIdentifierName()
{
return this.getSuperClassifierFacade().isValidIdentifierName();
}
/**
* Searches for the constraint with the specified 'name' on this model element, and if found
* translates it using the specified 'translation' from a translation library discovered by the
* framework.
* @see ModelElementFacade#translateConstraint(String name, String translation)
*/
public String translateConstraint(String name, String translation)
{
return this.getSuperClassifierFacade().translateConstraint(name, translation);
}
/**
* Translates all constraints belonging to this model element with the given 'translation'.
* @see ModelElementFacade#translateConstraints(String translation)
*/
public String[] translateConstraints(String translation)
{
return this.getSuperClassifierFacade().translateConstraints(translation);
}
/**
* Translates the constraints of the specified 'kind' belonging to this model element.
* @see ModelElementFacade#translateConstraints(String kind, String translation)
*/
public String[] translateConstraints(String kind, String translation)
{
return this.getSuperClassifierFacade().translateConstraints(kind, translation);
}
/**
* @see org.andromda.core.metafacade.MetafacadeBase#initialize()
*/
@Override
public void initialize()
{
this.getSuperClassifierFacade().initialize();
}
/**
* @return Object getSuperClassifierFacade().getValidationOwner()
* @see org.andromda.core.metafacade.MetafacadeBase#getValidationOwner()
*/
@Override
public Object getValidationOwner()
{
Object owner = this.getSuperClassifierFacade().getValidationOwner();
return owner;
}
/**
* @return String getSuperClassifierFacade().getValidationName()
* @see org.andromda.core.metafacade.MetafacadeBase#getValidationName()
*/
@Override
public String getValidationName()
{
String name = this.getSuperClassifierFacade().getValidationName();
return name;
}
/**
* @param validationMessages Collection<ModelValidationMessage>
* @see org.andromda.core.metafacade.MetafacadeBase#validateInvariants(Collection validationMessages)
*/
@Override
public void validateInvariants(Collection<ModelValidationMessage> validationMessages)
{
this.getSuperClassifierFacade().validateInvariants(validationMessages);
}
/**
* The property that stores the name of the metafacade.
*/
private static final String NAME_PROPERTY = "name";
private static final String FQNAME_PROPERTY = "fullyQualifiedName";
/**
* @see Object#toString()
*/
@Override
public String toString()
{
final StringBuilder toString = new StringBuilder(this.getClass().getName());
toString.append("[");
try
{
toString.append(Introspector.instance().getProperty(this, FQNAME_PROPERTY));
}
catch (final Throwable tryAgain)
{
try
{
toString.append(Introspector.instance().getProperty(this, NAME_PROPERTY));
}
catch (final Throwable ignore)
{
// - just ignore when the metafacade doesn't have a name or fullyQualifiedName property
}
}
toString.append("]");
return toString.toString();
}
} 