/// <summary>
/// Starts the serialization process. Takes the abstract of the graph and
/// constructs a NMLType proxy-like object which will be serialized via the
/// standard .Net XmlSerializer process.
/// </summary>
/// <param name="writer">An XmlWriter</param>
/// <param name="g">The GraphAbstract object to be serialized</param>
public void Serialize(XmlWriter writer, GraphAbstract g)
{
try
{
//the root of the NML
NMLType nml = new NMLType();
//add the version node
nml.Version = Assembly.GetExecutingAssembly().GetName().Version.ToString();
//the graph node
GraphType graph = new GraphType();
nml.Graph = graph;
//add the graph information
graph.GraphInformation = new GraphInformationType(g.GraphInformation);
//serialize the shapes
foreach (Shape s in g.Shapes)
{
graph.Items.Add(SerializeNode(s));
}
//serialize the connections
foreach (Connection c in g.Connections)
{
graph.Items.Add(SerializeEdge(c));
}
// foreach(DictionaryEntry de in keyList)
// {
// nml.Key.Add(BuildKeyType((String)de.Key));
// }
// serialize
XmlSerializer ser = new XmlSerializer(typeof(NMLType));
ser.Serialize(writer, nml);
}
catch (Exception exc)
{
site.OutputInfo(exc.Message, "NMLSerializer.Serialize", OutputInfoLevels.Exception);
}
catch
{
site.OutputInfo("Non-CLS exception caught.", "BinarySerializer.Serialize", OutputInfoLevels.Exception);
}
finally
{
}
}
/// <summary>
/// Deserializes the graph's xml
/// </summary>
/// <returns></returns>
public GraphAbstract Deserialize(XmlReader reader)
{
//very important; always use the same instantiation parameter of the XmlSerializer as
//you used for serialization!
XmlSerializer ser = new XmlSerializer(typeof(NMLType));
if (ser.CanDeserialize(reader))
{
NMLType gtype = ser.Deserialize(reader) as NMLType;
return(Deserialize(gtype));
}
else
{
throw new Exception("The supplied file cannot be deserialized to a graph (check the XML)");
}
}
/// <summary>
/// Deserializes the graphtype, here's where all the smart stuff happens
/// </summary>
/// <param name="gml">the graphtype which acts as an intermediate storage between XML and the GraphAbstract
/// </param>
/// <returns></returns>
private GraphAbstract Deserialize(NMLType gml)
{
GraphAbstract abs = new GraphAbstract();
#region Load the graph information
GraphType g = gml.Graph;
abs.GraphInformation = g.GraphInformation.ToGraphInformation();
#endregion
Shape shape = null;
ShapeType node;
DataType dt;
ConnectorType ct;
Connection con = null;
ConnectionType et;
string linePath = string.Empty; //see the split deserialization of the connection
FromToCollection ftc = new FromToCollection(); //temporary store for from-to relations of connections
Hashtable connectors = new Hashtable(); //temporary collection of connector
#region Loop over all items
for(int k =0; k<g.Items.Count;k++) //loop over all serialized items
{
try
{
if(g.Items[k] is ShapeType)
{
Trace.WriteLine("Node: " + (g.Items[k] as ShapeType).UID,"NMLSerializer.Deserialize");
node = g.Items[k] as ShapeType;
#region find out which type of shape needs to be instantiated
if(node!=null && node.InstanceKey!=string.Empty)
shape = GetShape(node.InstanceKey);
if(shape==null)
{
Trace.WriteLine("...but failed to instantiate the appropriate shape (missing or not loaded library?", "NMLSerializer.Deserialize");
continue;
}
#endregion
#region use the attribs again to reconstruct the props
for(int m=0; m<node.Data.Count;m++) //loop over the serialized data
{
if(node.Data[m] is DataType)
{
#region Handle data node
dt = node.Data[m] as DataType;
if(dt==null) continue;
foreach (PropertyInfo pi in shape.GetType().GetProperties())
{
if (Attribute.IsDefined(pi, typeof(GraphMLDataAttribute)))
{
try
{
if(pi.Name==dt.Name)
{
if(pi.GetIndexParameters().Length==0)
{
if(pi.PropertyType.Equals(typeof(int)))
pi.SetValue(shape,Convert.ToInt32(dt.Value[0]),null);
else if(pi.PropertyType.Equals(typeof(Color))) //Color is stored as an integer
pi.SetValue(shape,Color.FromArgb(int.Parse(dt.Value[0].ToString())),null);
else if(pi.PropertyType.Equals(typeof(string)))
pi.SetValue(shape,(string)(dt.Value[0]),null);
else if(pi.PropertyType.Equals(typeof(bool)))
pi.SetValue(shape,Convert.ToBoolean(dt.Value[0]),null);
else if(pi.PropertyType.Equals(typeof(Guid)))
pi.SetValue(shape,new Guid((string) dt.Value[0]),null);
else if(pi.PropertyType.Equals(typeof(float)))
pi.SetValue(shape, Convert.ToSingle(dt.Value[0]),null);
else if(pi.PropertyType.BaseType.Equals(typeof(Enum)))//yesyes, you can imp/exp enum types too
pi.SetValue(shape, Enum.Parse(pi.PropertyType,dt.Value[0].ToString()),null);
else if(dt.IsCollection)
{
#region Some explanations
/* OK, here's the deal.
* This part is related to the possibility to imp/exp property-collections from/to NML.
* However, since (see more specifically the ClassShape) the collections will usually be defined
* where the shapes is defined, i.e. in an external assembly, the collection-type is unknown.
* Importing/exporting collections to NML is itsel a problem and in this part of the code the data is reflected again.
* To bypass the problem that the collection-type is unknown I hereby assume that the collection can be built up again via
* a public constructor of the collection with argument 'ArrayList'. In the ArrayList the collection-elements are of type string[]
* whereby the order of the strings reflect the order of the GraphMLData-tagged properties of the collection elements.
* For example, the ClassPropertiesCollection has the required constructor and the ClassProperty object is instantiated via the string[] elements in the
* ArrayList.
* Of course, this brings some restriction but it's for the moment the most flexible way I have found.
* If the ClassProperty would itself have a property inheriting from CollectionBase this will not work...one has to draw a line somewhere.
* It's the price to pay for using reflection and external assemblies. The whole story can be forgotten if you link the shape-classes at compile-time.
* Remember; the Netron graphlib is more a toolkit than a all-in solution to all situations.
* However, the current implementation will cover, I beleive, 90% of the needs.
*/
#endregion
ArrayList list = new ArrayList();
for(int p =0; p<dt.Value.Count; p++) //loop over the collection elements
{
DataType dat = dt.Value[p] as DataType; //take a collection element
if(dat.IsCollection) //is it itself a collection?
{
string[] str = new string[dat.Value.Count];
for(int l=0;l<dat.Value.Count;l++)
{
if((dat.Value[l] as DataType).Value.Count>0)
str[l] = (string) (dat.Value[l] as DataType).Value[0];
else
str[l] = string.Empty;
}
list.Add(str);
}
else
{
list.Add(new string[]{(string) dat.Value[0]});
}
}
object o;
o = pi.PropertyType.GetConstructor(new Type[]{typeof(ArrayList)}).Invoke(new Object[]{list});
pi.SetValue(shape,o,null);
Trace.WriteLine("'" + dt.Name + "' is an array type","NMLSeriliazer.Deserialize");
}
}
else
pi.SetValue(shape,dt.Value,null);
Trace.WriteLine("'" + dt.Name + "' deserialized.","NMLSeriliazer.Deserialize");
break;
}
}
catch(Exception exc)
{
Trace.WriteLine("Failed '" + dt.Name +"': " + exc.Message,"NMLSeriliazer.Deserialize");
continue;//just try to make the best out of it
}
}
}
#endregion
}
else if (node.Data[m] is ConnectorType)
{
#region Handle connector data
ct = node.Data[m] as ConnectorType;
foreach(Connector c in shape.Connectors)
if(c.Name==ct.Name)
{
c.UID = new Guid(ct.UID);
break;
}
#endregion
}
}
#endregion
//at this point the shape is fully deserialized
//but we still need to assign the ambient properties,
//i.e. the properties associated to the current hosting of the control
if(shape !=null)
{
shape.Site = site;
shape.PostDeserialization();
shape.Font = site.Font;
//shape.FitSize(false);
abs.Shapes.Add(shape);
//keep the references to the connectors, to be used when creating the connections
foreach(Connector cor in shape.Connectors)
connectors.Add(cor.UID.ToString(),cor);
}
}
else if(g.Items[k] is ConnectionType)
{
#region handle the edge
//we cannot create the connection here since not all shapes have been instantiated yet
//keep the edges in temp collection, treated in next loop
et = g.Items[k] as ConnectionType;
con = new Connection(site);
con.Font = site.Font;
con.UID = new Guid(et.ID);
Trace.WriteLine("Connection: " + et.ID,"NMLSeriliazer.Deserialize");
#region use the attribs to reconstruct the props
for(int m=0; m<et.Data.Count;m++) //loop over the serialized data
{
if(et.Data[m] is DataType)
{
#region Handle data node, same as the shape
dt = et.Data[m] as DataType;
if(dt==null) continue;
foreach (PropertyInfo pi in con.GetType().GetProperties())
{
if (Attribute.IsDefined(pi, typeof(GraphMLDataAttribute)))
{
try
{
if(pi.Name==dt.Name)
{
if(dt.Name=="LinePath")
{
//the LinePath will not work without non-null From and To, so set it afterwards
linePath = dt.Value[0].ToString();
}
else if(pi.GetIndexParameters().Length==0)
{
if(pi.PropertyType.Equals(typeof(int)))
pi.SetValue(con,Convert.ToInt32(dt.Value[0]),null);
else if(pi.PropertyType.Equals(typeof(Color))) //Color is stored as an integer
pi.SetValue(con,Color.FromArgb(int.Parse(dt.Value[0].ToString())),null);
else if(pi.PropertyType.Equals(typeof(string)))
pi.SetValue(con,(string)(dt.Value[0]),null);
else if(pi.PropertyType.Equals(typeof(bool)))
pi.SetValue(con,Convert.ToBoolean(dt.Value[0]),null);
else if(pi.PropertyType.Equals(typeof(Guid)))
pi.SetValue(con,new Guid((string) dt.Value[0]),null);
else if(pi.PropertyType.Equals(typeof(float)))
pi.SetValue(con, Convert.ToSingle(dt.Value[0]),null);
else if (pi.PropertyType.Equals(typeof(ConnectionWeight)))
pi.SetValue(con, Enum.Parse(typeof(ConnectionWeight),dt.Value[0].ToString()),null);
else if (pi.PropertyType.Equals(typeof(System.Drawing.Drawing2D.DashStyle)))
pi.SetValue(con, Enum.Parse(typeof(System.Drawing.Drawing2D.DashStyle),dt.Value[0].ToString()),null);
}
else
pi.SetValue(con,dt.Value,null);
Trace.WriteLine("'" + dt.Name + "' deserialized.","NMLSeriliazer.Deserialize");
break;
}
}
catch(Exception exc)
{
Trace.WriteLine("Failed '" + dt.Name +"': " + exc.Message,"NMLSeriliazer.Deserialize");
continue;//just try to make the best out of it
}
}
}
#endregion
}
}
#endregion
ftc.Add(new FromTo(et.Sourceport,et.Targetport, con));
#endregion
}
}
catch(Exception exc)
{
Trace.WriteLine(exc.Message,"NMLSeriliazer.Deserialize");
continue;
}
}//loop over items in the graph-XML
#endregion
#region now for the edges;
//loop over the FromTo collections and pick up the corresponding connectors
for(int k=0; k<ftc.Count; k++)
{
try
{
con = ftc[k].Connection;
con.From = connectors[ftc[k].From] as Connector;
con.To = connectors[ftc[k].To] as Connector;
con.From.Connections.Add(con);//if From is null we'll fail in the catch and continue
con.LinePath = linePath; //only setable after the From and To are found
con.To.Connections.Add(con);
abs.Insert(con);
Trace.WriteLine("Connection '" + con.UID + "' added.","NMLSeriliazer.Deserialize");
}
catch(Exception exc)
{
Trace.WriteLine("Connection failed: " + exc.Message,"NMLSeriliazer.Deserialize");
continue; //make the best of it
}
}
#endregion
// for(int n=0; n<pcs.Count; n++)
// {
// from = pcs[n].ChildShape;
// to = abs.Shapes[pcs[n].Parent];
// con = new Connection(from, to );
// abs.Connections.Add(con);
// con.site = site;
// if(pcs[n].ChildShape.visible)
// con.visible = true;
// from.connection = con; //a lot of crossing...to make life easy really
// from.parentNode =to;
// to.childNodes.Add(from);
//
//
// }
return abs;
}
/// <summary>
/// Starts the serialization process. Takes the abstract of the graph and
/// constructs a NMLType proxy-like object which will be serialized via the
/// standard .Net XmlSerializer process.
/// </summary>
/// <param name="writer">An XmlWriter</param>
/// <param name="g">The GraphAbstract object to be serialized</param>
public void Serialize(XmlWriter writer, GraphAbstract g )
{
try
{
//the root of the NML
NMLType nml = new NMLType();
//add the version node
nml.Version = Assembly.GetExecutingAssembly().GetName().Version.ToString();
//the graph node
GraphType graph = new GraphType();
nml.Graph = graph;
//add the graph information
graph.GraphInformation = new GraphInformationType(g.GraphInformation);
//serialize the shapes
foreach ( Shape s in g.Shapes )
graph.Items.Add(SerializeNode(s));
//serialize the connections
foreach(Connection c in g.Connections)
graph.Items.Add(SerializeEdge(c));
// foreach(DictionaryEntry de in keyList)
// {
// nml.Key.Add(BuildKeyType((String)de.Key));
// }
// serialize
XmlSerializer ser = new XmlSerializer(typeof(NMLType));
ser.Serialize(writer,nml);
}
catch(Exception exc)
{
site.OutputInfo(exc.Message, "NMLSerializer.Serialize", OutputInfoLevels.Exception);
}
catch
{
site.OutputInfo("Non-CLS exception caught.", "BinarySerializer.Serialize", OutputInfoLevels.Exception);
}
finally
{
}
}
/// <summary>
/// Deserializes the graphtype, here's where all the smart stuff happens
/// </summary>
/// <param name="gml">the graphtype which acts as an intermediate storage between XML and the GraphAbstract
/// </param>
/// <returns></returns>
private GraphAbstract Deserialize(NMLType gml)
{
GraphAbstract abs = new GraphAbstract();
#region Load the graph information
GraphType g = gml.Graph;
abs.GraphInformation = g.GraphInformation.ToGraphInformation();
#endregion
Shape shape = null;
ShapeType node;
DataType dt;
ConnectorType ct;
Connection con = null;
ConnectionType et;
string linePath = string.Empty; //see the split deserialization of the connection
FromToCollection ftc = new FromToCollection(); //temporary store for from-to relations of connections
Hashtable connectors = new Hashtable(); //temporary collection of connector
#region Loop over all items
for (int k = 0; k < g.Items.Count; k++) //loop over all serialized items
{
try
{
if (g.Items[k] is ShapeType)
{
Trace.WriteLine("Node: " + (g.Items[k] as ShapeType).UID, "NMLSerializer.Deserialize");
node = g.Items[k] as ShapeType;
#region find out which type of shape needs to be instantiated
if (node != null && node.InstanceKey != string.Empty)
{
shape = GetShape(node.InstanceKey);
}
if (shape == null)
{
Trace.WriteLine("...but failed to instantiate the appropriate shape (missing or not loaded library?", "NMLSerializer.Deserialize");
continue;
}
#endregion
#region use the attribs again to reconstruct the props
for (int m = 0; m < node.Data.Count; m++) //loop over the serialized data
{
if (node.Data[m] is DataType)
{
#region Handle data node
dt = node.Data[m] as DataType;
if (dt == null)
{
continue;
}
foreach (PropertyInfo pi in shape.GetType().GetProperties())
{
if (Attribute.IsDefined(pi, typeof(GraphMLDataAttribute)))
{
try
{
if (pi.Name == dt.Name)
{
if (pi.GetIndexParameters().Length == 0)
{
if (pi.PropertyType.Equals(typeof(int)))
{
pi.SetValue(shape, Convert.ToInt32(dt.Value[0]), null);
}
else if (pi.PropertyType.Equals(typeof(Color))) //Color is stored as an integer
{
pi.SetValue(shape, Color.FromArgb(int.Parse(dt.Value[0].ToString())), null);
}
else if (pi.PropertyType.Equals(typeof(string)))
{
pi.SetValue(shape, (string)(dt.Value[0]), null);
}
else if (pi.PropertyType.Equals(typeof(bool)))
{
pi.SetValue(shape, Convert.ToBoolean(dt.Value[0]), null);
}
else if (pi.PropertyType.Equals(typeof(Guid)))
{
pi.SetValue(shape, new Guid((string)dt.Value[0]), null);
}
else if (pi.PropertyType.Equals(typeof(float)))
{
pi.SetValue(shape, Convert.ToSingle(dt.Value[0]), null);
}
else if (pi.PropertyType.BaseType.Equals(typeof(Enum))) //yesyes, you can imp/exp enum types too
{
pi.SetValue(shape, Enum.Parse(pi.PropertyType, dt.Value[0].ToString()), null);
}
else if (dt.IsCollection)
{
#region Some explanations
/* OK, here's the deal.
* This part is related to the possibility to imp/exp property-collections from/to NML.
* However, since (see more specifically the ClassShape) the collections will usually be defined
* where the shapes is defined, i.e. in an external assembly, the collection-type is unknown.
* Importing/exporting collections to NML is itsel a problem and in this part of the code the data is reflected again.
* To bypass the problem that the collection-type is unknown I hereby assume that the collection can be built up again via
* a public constructor of the collection with argument 'ArrayList'. In the ArrayList the collection-elements are of type string[]
* whereby the order of the strings reflect the order of the GraphMLData-tagged properties of the collection elements.
* For example, the ClassPropertiesCollection has the required constructor and the ClassProperty object is instantiated via the string[] elements in the
* ArrayList.
* Of course, this brings some restriction but it's for the moment the most flexible way I have found.
* If the ClassProperty would itself have a property inheriting from CollectionBase this will not work...one has to draw a line somewhere.
* It's the price to pay for using reflection and external assemblies. The whole story can be forgotten if you link the shape-classes at compile-time.
* Remember; the Netron graphlib is more a toolkit than a all-in solution to all situations.
* However, the current implementation will cover, I beleive, 90% of the needs.
*/
#endregion
ArrayList list = new ArrayList();
for (int p = 0; p < dt.Value.Count; p++) //loop over the collection elements
{
DataType dat = dt.Value[p] as DataType; //take a collection element
if (dat.IsCollection) //is it itself a collection?
{
string[] str = new string[dat.Value.Count];
for (int l = 0; l < dat.Value.Count; l++)
{
if ((dat.Value[l] as DataType).Value.Count > 0)
{
str[l] = (string)(dat.Value[l] as DataType).Value[0];
}
else
{
str[l] = string.Empty;
}
}
list.Add(str);
}
else
{
list.Add(new string[] { (string)dat.Value[0] });
}
}
object o;
o = pi.PropertyType.GetConstructor(new Type[] { typeof(ArrayList) }).Invoke(new Object[] { list });
pi.SetValue(shape, o, null);
Trace.WriteLine("'" + dt.Name + "' is an array type", "NMLSeriliazer.Deserialize");
}
}
else
{
pi.SetValue(shape, dt.Value, null);
}
Trace.WriteLine("'" + dt.Name + "' deserialized.", "NMLSeriliazer.Deserialize");
break;
}
}
catch (Exception exc)
{
Trace.WriteLine("Failed '" + dt.Name + "': " + exc.Message, "NMLSeriliazer.Deserialize");
continue; //just try to make the best out of it
}
}
}
#endregion
}
else if (node.Data[m] is ConnectorType)
{
#region Handle connector data
ct = node.Data[m] as ConnectorType;
foreach (Connector c in shape.Connectors)
{
if (c.Name == ct.Name)
{
c.UID = new Guid(ct.UID);
break;
}
}
#endregion
}
}
#endregion
//at this point the shape is fully deserialized
//but we still need to assign the ambient properties,
//i.e. the properties associated to the current hosting of the control
if (shape != null)
{
shape.Site = site;
shape.PostDeserialization();
shape.Font = site.Font;
//shape.FitSize(false);
abs.Shapes.Add(shape);
//keep the references to the connectors, to be used when creating the connections
foreach (Connector cor in shape.Connectors)
{
connectors.Add(cor.UID.ToString(), cor);
}
}
}
else if (g.Items[k] is ConnectionType)
{
#region handle the edge
//we cannot create the connection here since not all shapes have been instantiated yet
//keep the edges in temp collection, treated in next loop
et = g.Items[k] as ConnectionType;
con = new Connection(site);
con.Font = site.Font;
con.UID = new Guid(et.ID);
Trace.WriteLine("Connection: " + et.ID, "NMLSeriliazer.Deserialize");
#region use the attribs to reconstruct the props
for (int m = 0; m < et.Data.Count; m++) //loop over the serialized data
{
if (et.Data[m] is DataType)
{
#region Handle data node, same as the shape
dt = et.Data[m] as DataType;
if (dt == null)
{
continue;
}
foreach (PropertyInfo pi in con.GetType().GetProperties())
{
if (Attribute.IsDefined(pi, typeof(GraphMLDataAttribute)))
{
try
{
if (pi.Name == dt.Name)
{
if (dt.Name == "LinePath")
{
//the LinePath will not work without non-null From and To, so set it afterwards
linePath = dt.Value[0].ToString();
}
else if (pi.GetIndexParameters().Length == 0)
{
if (pi.PropertyType.Equals(typeof(int)))
{
pi.SetValue(con, Convert.ToInt32(dt.Value[0]), null);
}
else if (pi.PropertyType.Equals(typeof(Color))) //Color is stored as an integer
{
pi.SetValue(con, Color.FromArgb(int.Parse(dt.Value[0].ToString())), null);
}
else if (pi.PropertyType.Equals(typeof(string)))
{
pi.SetValue(con, (string)(dt.Value[0]), null);
}
else if (pi.PropertyType.Equals(typeof(bool)))
{
pi.SetValue(con, Convert.ToBoolean(dt.Value[0]), null);
}
else if (pi.PropertyType.Equals(typeof(Guid)))
{
pi.SetValue(con, new Guid((string)dt.Value[0]), null);
}
else if (pi.PropertyType.Equals(typeof(float)))
{
pi.SetValue(con, Convert.ToSingle(dt.Value[0]), null);
}
else if (pi.PropertyType.Equals(typeof(ConnectionWeight)))
{
pi.SetValue(con, Enum.Parse(typeof(ConnectionWeight), dt.Value[0].ToString()), null);
}
}
else
{
pi.SetValue(con, dt.Value, null);
}
Trace.WriteLine("'" + dt.Name + "' deserialized.", "NMLSeriliazer.Deserialize");
break;
}
}
catch (Exception exc)
{
Trace.WriteLine("Failed '" + dt.Name + "': " + exc.Message, "NMLSeriliazer.Deserialize");
continue; //just try to make the best out of it
}
}
}
#endregion
}
}
#endregion
ftc.Add(new FromTo(et.Sourceport, et.Targetport, con));
#endregion
}
}
catch (Exception exc)
{
Trace.WriteLine(exc.Message, "NMLSeriliazer.Deserialize");
continue;
}
} //loop over items in the graph-XML
#endregion
#region now for the edges;
//loop over the FromTo collections and pick up the corresponding connectors
for (int k = 0; k < ftc.Count; k++)
{
try
{
con = ftc[k].Connection;
con.From = connectors[ftc[k].From] as Connector;
con.To = connectors[ftc[k].To] as Connector;
con.From.Connections.Add(con); //if From is null we'll fail in the catch and continue
con.LinePath = linePath; //only setable after the From and To are found
con.To.Connections.Add(con);
abs.Insert(con);
Trace.WriteLine("Connection '" + con.UID + "' added.", "NMLSeriliazer.Deserialize");
}
catch (Exception exc)
{
Trace.WriteLine("Connection failed: " + exc.Message, "NMLSeriliazer.Deserialize");
continue; //make the best of it
}
}
#endregion
// for(int n=0; n<pcs.Count; n++)
// {
// from = pcs[n].ChildShape;
// to = abs.Shapes[pcs[n].Parent];
// con = new Connection(from, to );
// abs.Connections.Add(con);
// con.site = site;
// if(pcs[n].ChildShape.visible)
// con.visible = true;
// from.connection = con; //a lot of crossing...to make life easy really
// from.parentNode =to;
// to.childNodes.Add(from);
//
//
// }
return(abs);
}
