public override void SetValue(object rawValue)
{
SifElementPointer immediateParent = (SifElementPointer)Parent;
SifElement parentElement = immediateParent.Element as SifElement;
SifSimpleType sst = GetSIFSimpleTypeValue(fElementDef, rawValue);
parentElement.SetField(fElementDef, sst);
}
/// <summary>
/// Called on the subclass when a specific NodePointer is requested by SIFXPath
/// </summary>
/// <param name="parent"></param>
/// <param name="element"></param>
/// <returns></returns>
protected override INodePointer GetNodePointer(SifElementPointer parent, Element element)
{
if (element is SimpleField)
{
return(SimpleFieldPointer.Create(parent, (SimpleField)element));
}
else
{
return(SifElementPointer.Create(parent, (SifElement)element, parent.Version));
}
}
/// <summary>
/// Called on the subclass when a specific NodePointer is requested by SIFXPath
/// </summary>
/// <param name="parent"></param>
/// <param name="element"></param>
/// <returns></returns>
protected override INodePointer GetNodePointer( SifElementPointer parent, Element element )
{
if ( element is SimpleField )
{
return SimpleFieldPointer.Create( parent, (SimpleField) element );
}
else
{
return SifElementPointer.Create( parent, (SifElement) element, parent.Version );
}
}
public void testFauxAttribute010()
{
SifElementPointer sep = new SifElementPointer(null, new StudentPersonal(), SifVersion.SIF15r1);
FauxAttribute fa = new FauxAttribute(sep, "Type", "Projected");
// Assert base functionality
Assert.AreEqual( "Type", fa.Name );
Assert.AreEqual("Projected", fa.Value);
Assert.AreEqual(sep, fa.Parent );
// Assert XPath functionality
Assert.AreEqual( XPathNodeType.Attribute, fa.NodeType );
}
internal AdkAttributeIterator(SifElementPointer parent) : base(parent)
{
SifVersion version = parent.Version;
SifElement node = (SifElement)parent.Node;
// Capture all fields
foreach (SimpleField field in node.GetFields())
{
IElementDef fieldDef = field.ElementDef;
if (fieldDef.IsSupported(version) &&
fieldDef.IsAttribute(version))
{
addNodeToIterate(field);
}
}
}
internal AdkAttributeIterator( SifElementPointer parent )
: base(parent)
{
SifVersion version = parent.Version;
SifElement node = (SifElement) parent.Node;
// Capture all fields
foreach ( SimpleField field in node.GetFields() )
{
IElementDef fieldDef = field.ElementDef;
if ( fieldDef.IsSupported( version )
&& fieldDef.IsAttribute( version ) )
{
addNodeToIterate( field );
}
}
}
/// <summary>
/// Creates a new SifXPathContext
/// </summary>
/// <param name="parent"></param>
/// <param name="context"></param>
private SifXPathContext( SifXPathContext parent, SifElement context )
{
if ( parent != null )
{
fContext = parent.fContext;
}
else
{
fContext = new SifXsltContext();
fContext.AddFunctions( "adk", new ClassFunctions( typeof ( AdkFunctions ), null ) );
}
SifVersion version = context.SifVersion;
if( version == null )
{
version = SifVersion.LATEST;
}
fContextElement = context;
fContextPointer = new SifElementPointer( null, fContextElement, version );
fDefaultNavigator = new SifXPathNavigator( fContext, fContextPointer );
}
/// <summary>
/// Creates a new SifXPathContext
/// </summary>
/// <param name="parent"></param>
/// <param name="context"></param>
private SifXPathContext(SifXPathContext parent, SifElement context)
{
if (parent != null)
{
fContext = parent.fContext;
}
else
{
fContext = new SifXsltContext();
fContext.AddFunctions("adk", new ClassFunctions(typeof(AdkFunctions), null));
}
SifVersion version = context.SifVersion;
if (version == null)
{
version = SifVersion.LATEST;
}
fContextElement = context;
fContextPointer = new SifElementPointer(null, fContextElement, version);
fDefaultNavigator = new SifXPathNavigator(fContext, fContextPointer);
}
/// <summary>
/// Creates a new NodePointer representing the SimpleField
/// </summary>
/// <param name="pointerParent"></param>
/// <param name="field"></param>
/// <returns></returns>
public static INodePointer Create(
SifElementPointer pointerParent, SimpleField field)
{
SifVersion version = pointerParent.Version;
if (pointerParent.IsLegacyVersion)
{
IElementDef fieldDef = field.ElementDef;
IRenderSurrogate rs = fieldDef.GetVersionInfo(version).GetSurrogate();
if (rs != null)
{
return(rs.CreateNodePointer(pointerParent, field, version));
}
}
if (field.ElementDef.IsAttribute(version))
{
return(new SimpleFieldAttributePointer(pointerParent, field, version));
}
else
{
return(new SimpleFieldElementPointer(pointerParent, field, version));
}
}
/// <summary>
/// Creates a new NodePointer representing the SimpleField
/// </summary>
/// <param name="pointerParent"></param>
/// <param name="field"></param>
/// <returns></returns>
public static INodePointer Create(
SifElementPointer pointerParent, SimpleField field )
{
SifVersion version = pointerParent.Version;
if ( pointerParent.IsLegacyVersion )
{
IElementDef fieldDef = field.ElementDef;
IRenderSurrogate rs = fieldDef.GetVersionInfo( version ).GetSurrogate();
if ( rs != null )
{
return rs.CreateNodePointer( pointerParent, field, version );
}
}
if ( field.ElementDef.IsAttribute( version ) )
{
return new SimpleFieldAttributePointer( pointerParent, field, version );
}
else
{
return new SimpleFieldElementPointer( pointerParent, field, version );
}
}
public AdkElementIterator( SifElementPointer parent, IList<Element> nodesToIterate )
: base(parent, nodesToIterate)
{
}
/// <summary>
/// Creates a new instance of ADKNodeIterator
/// </summary>
/// <param name="parent"></param>
/// <param name="nodesToIterate"></param>
protected AdkNodeIterator( SifElementPointer parent,
IList<Element> nodesToIterate )
{
fParent = parent;
fChildNodes = nodesToIterate;
}
/// <summary>
/// Creates a new instance of ADKNodeIterator
/// </summary>
/// <param name="parent"></param>
protected AdkNodeIterator( SifElementPointer parent )
{
fParent = parent;
fChildNodes = new List<Element>();
}
/// <summary> /// Called on the subclass when a specific NodePointer is requested by SIFXPath /// </summary> /// <param name="parent"></param> /// <param name="element"></param> /// <returns></returns> protected abstract INodePointer GetNodePointer( SifElementPointer parent, Element element );
/// <summary> /// Called on the subclass when a specific NodePointer is requested by SIFXPath /// </summary> /// <param name="parent"></param> /// <param name="element"></param> /// <returns></returns> protected abstract INodePointer GetNodePointer(SifElementPointer parent, Element element);
/// <summary>
/// Manually builds out a path to support the necessary mapping needs of the
/// ADK. By default, the JXPath implementation does not allow
/// context-dependend predicates (e.g. PhoneNumber[@Type='0096'] to be used
/// in XPaths that create the path. This implementation manually steps
/// through the XPath and builds it out. It's primary intent is to provide
/// the behavior that was present in the ADK before JXPath was used for
/// mapping
/// </summary>
/// <param name="expr">The Path expression to build out</param>
/// <param name="context"></param>
/// <returns></returns>
private INodePointer BuildADKPathWithPredicates(String expr, XsltContext context)
{
// Use the set of expression steps to determine which parts of the
// path already exist. Note that the order of evaluation used is optimized
// for first-time creation of elements. In other words, the path chosen was
// to evalaute the expression steps from the beginning rather than the end
// because for outbound mappings, that order will generally be the most efficient
AdkXPathStep[] steps = XPathParser.Parse(expr);
int currentStep = 0;
StringBuilder pathSoFar = new StringBuilder();
INodePointer parent = fContextPointer;
INodePointer current = null;
for ( ; currentStep < steps.Length; currentStep++)
{
current = FindChild(fDefaultNavigator, pathSoFar, steps[currentStep]);
if (current == null)
{
break;
}
pathSoFar.Append("/");
pathSoFar.Append(steps[currentStep].ToString());
parent = current;
}
if (current != null)
{
// We traversed the entire path and came up with a result.
// That means that the element we are trying to build the
// path to already exists. We will not create this path, so
// return null;
return(null);
}
// We've traversed down to the level where we think we need to
// add a child. However, there are cases where this is not the proper
// location. For example, in SIF 1.5r1, the StudentAddressList element is
// repeatable and Address is not. It would not be proper to add a new Address
// element under StudentAddressList. Instead, the algorithm needs to back
// up the stack until it reaches the next repeatable element for the current
// version of SIF
// The following code is primarily in place for the StudentAddressList case, which is
// why the isContextDependent() logic applies. Currently, there is no known other place
// where this checking needs to occur.
if (currentStep > 0 && steps[currentStep].IsContextDependent())
{
int step = currentStep;
INodePointer stepParent = parent;
while (step > -1)
// don't evaluate step 0 at the root of the object because this problem doesn't apply there
{
if (parent is SifElementPointer)
{
SifElementPointer sifParentPointer = (SifElementPointer)stepParent;
AdkNodeTest nt = steps[step].NodeTest;
if (nt is AdkNodeNameTest)
{
SifElementPointer.AddChildDirective result =
sifParentPointer.GetAddChildDirective(((AdkNodeNameTest)nt).NodeName);
if (result != SifElementPointer.AddChildDirective.DONT_ADD_NOT_REPEATABLE)
{
break;
}
}
}
else
{
break;
}
step--;
stepParent = stepParent.Parent;
}
if (step > -1 && step != currentStep)
{
currentStep = step;
parent = stepParent;
}
}
// At this point, we have a parent element and the index of the current
// step to evaluate
//InitialContext context = new InitialContext( new RootContext( this, (NodePointer) getContextPointer()));
for ( ; currentStep < steps.Length; currentStep++)
{
AdkNodeTest nt = steps[currentStep].NodeTest;
if (nt is AdkNodeNameTest)
{
current = parent.CreateChild(this, ((AdkNodeNameTest)nt).NodeName, 0);
if (current == null)
{
throw new ArgumentException("Cannot evaluate expression step: " + steps[currentStep]);
}
foreach (AdkExpression predicate in steps[currentStep].Predicates)
{
CreatePredicateValues(current, predicate, context);
}
}
else
{
throw new ArgumentException("Cannot evaluate expression step: " + steps[currentStep]);
}
parent = current;
}
// At the end, the 'parent' variable will contain the last element created by this function
return(parent);
}
public AdkElementIterator(SifElementPointer parent, IList <Element> nodesToIterate)
: base(parent, nodesToIterate)
{
}
/// <summary>
/// Creates a new instance of ADKNodeIterator
/// </summary>
/// <param name="parent"></param>
/// <param name="nodesToIterate"></param>
protected AdkNodeIterator(SifElementPointer parent,
IList <Element> nodesToIterate)
{
fParent = parent;
fChildNodes = nodesToIterate;
}
private AdkAttributeIterator( SifElementPointer parent, IList<Element> children )
: base(parent)
{
fChildNodes = children;
}
/// <summary>
/// Called on the subclass when a specific NodePointer is requested by SIFXPath
/// </summary>
/// <param name="parent"></param>
/// <param name="element"></param>
/// <returns></returns>
protected override INodePointer GetNodePointer(SifElementPointer parent, Element element)
{
return(SimpleFieldPointer.Create(parent, (SimpleField)element));
}
private AdkAttributeIterator(SifElementPointer parent, IList <Element> children) : base(parent)
{
fChildNodes = children;
}
/// <summary>
/// Called on the subclass when a specific NodePointer is requested by SIFXPath
/// </summary>
/// <param name="parent"></param>
/// <param name="element"></param>
/// <returns></returns>
protected override INodePointer GetNodePointer( SifElementPointer parent, Element element )
{
return SimpleFieldPointer.Create( parent, (SimpleField) element );
}
/// <summary>
/// Creates a new instance of ADKNodeIterator
/// </summary>
/// <param name="parent"></param>
protected AdkNodeIterator(SifElementPointer parent)
{
fParent = parent;
fChildNodes = new List <Element>();
}
