| private OnRequestsFunctionNamePrompt ( Object sender, Dynamo.Models.FunctionNamePromptEventArgs e ) : void | ||
| sender | Object | |
| e | Dynamo.Models.FunctionNamePromptEventArgs | |
| return | void | |
/// <summary>
/// Collapse a set of nodes in a given workspace.
/// </summary>
/// <param name="dynamoModel">The current DynamoModel</param>
/// <param name="selectedNodes"> The function definition for the user-defined node </param>
/// <param name="currentWorkspace"> The workspace where</param>
/// <param name="args"></param>
public static void Collapse(DynamoModel dynamoModel, IEnumerable<NodeModel> selectedNodes, WorkspaceModel currentWorkspace, FunctionNamePromptEventArgs args = null)
{
var selectedNodeSet = new HashSet<NodeModel>(selectedNodes);
if (args == null || !args.Success)
{
args = new FunctionNamePromptEventArgs();
dynamoModel.OnRequestsFunctionNamePrompt(null, args);
if (!args.Success)
{
return;
}
}
// Note that undoable actions are only recorded for the "currentWorkspace",
// the nodes which get moved into "newNodeWorkspace" are not recorded for undo,
// even in the new workspace. Their creations will simply be treated as part of
// the opening of that new workspace (i.e. when a user opens a file, she will
// not expect the nodes that show up to be undoable).
//
// After local nodes are moved into "newNodeWorkspace" as the result of
// conversion, if user performs an undo, new set of nodes will be created in
// "currentWorkspace" (not moving those nodes in the "newNodeWorkspace" back
// into "currentWorkspace"). In another word, undo recording is on a per-
// workspace basis, it does not work across different workspaces.
//
UndoRedoRecorder undoRecorder = currentWorkspace.UndoRecorder;
using (undoRecorder.BeginActionGroup())
{
var newNodeWorkspace = new CustomNodeWorkspaceModel(
dynamoModel,
args.Name,
args.Category,
args.Description,
0,
0) { WatchChanges = false, HasUnsavedChanges = true };
var newNodeDefinition = new CustomNodeDefinition(Guid.NewGuid())
{
WorkspaceModel = newNodeWorkspace
};
currentWorkspace.DisableReporting();
#region Determine Inputs and Outputs
//Step 1: determine which nodes will be inputs to the new node
var inputs =
new HashSet<Tuple<NodeModel, int, Tuple<int, NodeModel>>>(
selectedNodeSet.SelectMany(
node =>
Enumerable.Range(0, node.InPortData.Count)
.Where(node.HasConnectedInput)
.Select(data => Tuple.Create(node, data, node.Inputs[data]))
.Where(input => !selectedNodeSet.Contains(input.Item3.Item2))));
var outputs =
new HashSet<Tuple<NodeModel, int, Tuple<int, NodeModel>>>(
selectedNodeSet.SelectMany(
node =>
Enumerable.Range(0, node.OutPortData.Count)
.Where(node.HasOutput)
.SelectMany(
data =>
node.Outputs[data].Where(
output => !selectedNodeSet.Contains(output.Item2))
.Select(output => Tuple.Create(node, data, output)))));
#endregion
#region Detect 1-node holes (higher-order function extraction)
var curriedNodeArgs =
new HashSet<NodeModel>(
inputs.Select(x => x.Item3.Item2)
.Intersect(outputs.Select(x => x.Item3.Item2))).Select(
outerNode =>
{
//var node = new Apply1();
var node = newNodeWorkspace.AddNode<Apply1>();
node.SetNickNameFromAttribute();
node.DisableReporting();
node.X = outerNode.X;
node.Y = outerNode.Y;
//Fetch all input ports
// in order
// that have inputs
// and whose input comes from an inner node
List<int> inPortsConnected =
Enumerable.Range(0, outerNode.InPortData.Count)
.Where(
x =>
outerNode.HasInput(x)
&& selectedNodeSet.Contains(
outerNode.Inputs[x].Item2))
.ToList();
var nodeInputs =
outputs.Where(output => output.Item3.Item2 == outerNode)
.Select(
output =>
new
{
InnerNodeInputSender = output.Item1,
OuterNodeInPortData = output.Item3.Item1
})
.ToList();
nodeInputs.ForEach(_ => node.AddInput());
node.RegisterAllPorts();
return
new
{
OuterNode = outerNode,
InnerNode = node,
Outputs =
inputs.Where(
input => input.Item3.Item2 == outerNode)
.Select(input => input.Item3.Item1),
Inputs = nodeInputs,
OuterNodePortDataList = inPortsConnected
};
}).ToList();
#endregion
#region UI Positioning Calculations
double avgX = selectedNodeSet.Average(node => node.X);
double avgY = selectedNodeSet.Average(node => node.Y);
double leftMost = selectedNodeSet.Min(node => node.X);
double topMost = selectedNodeSet.Min(node => node.Y);
double rightMost = selectedNodeSet.Max(node => node.X + node.Width);
#endregion
#region Handle full selected connectors
// Step 2: Determine all the connectors whose start/end owners are
// both in the selection set, and then move them from the current
// workspace into the new workspace.
var fullySelectedConns =
new HashSet<ConnectorModel>(
currentWorkspace.Connectors.Where(
conn =>
{
bool startSelected = selectedNodeSet.Contains(conn.Start.Owner);
bool endSelected = selectedNodeSet.Contains(conn.End.Owner);
return startSelected && endSelected;
}));
foreach (var ele in fullySelectedConns)
{
undoRecorder.RecordDeletionForUndo(ele);
currentWorkspace.Connectors.Remove(ele);
}
#endregion
#region Handle partially selected connectors
// Step 3: Partially selected connectors (either one of its start
// and end owners is in the selection) are to be destroyed.
var partiallySelectedConns =
currentWorkspace.Connectors.Where(
conn =>
selectedNodeSet.Contains(conn.Start.Owner)
|| selectedNodeSet.Contains(conn.End.Owner)).ToList();
foreach (ConnectorModel connector in partiallySelectedConns)
{
undoRecorder.RecordDeletionForUndo(connector);
connector.NotifyConnectedPortsOfDeletion();
currentWorkspace.Connectors.Remove(connector);
}
#endregion
#region Transfer nodes and connectors to new workspace
// Step 4: move all nodes to new workspace remove from old
// PB: This could be more efficiently handled by a copy paste, but we
// are preservering the node
foreach (var ele in selectedNodeSet)
{
undoRecorder.RecordDeletionForUndo(ele);
ele.SaveResult = false;
currentWorkspace.Nodes.Remove(ele);
ele.Workspace = newNodeWorkspace;
}
// add to new
newNodeWorkspace.Nodes.AddRange(selectedNodeSet);
newNodeWorkspace.Connectors.AddRange(fullySelectedConns);
foreach (var node in newNodeWorkspace.Nodes)
node.DisableReporting();
double leftShift = leftMost - 250;
foreach (NodeModel node in newNodeWorkspace.Nodes)
{
node.X = node.X - leftShift;
node.Y = node.Y - topMost;
}
#endregion
#region Process inputs
var inConnectors = new List<Tuple<NodeModel, int>>();
var uniqueInputSenders = new Dictionary<Tuple<NodeModel, int>, Symbol>();
//Step 3: insert variables (reference step 1)
foreach (var input in Enumerable.Range(0, inputs.Count).Zip(inputs, Tuple.Create))
{
int inputIndex = input.Item1;
NodeModel inputReceiverNode = input.Item2.Item1;
int inputReceiverData = input.Item2.Item2;
NodeModel inputNode = input.Item2.Item3.Item2;
int inputData = input.Item2.Item3.Item1;
Symbol node;
var key = Tuple.Create(inputNode, inputData);
if (uniqueInputSenders.ContainsKey(key))
{
node = uniqueInputSenders[key];
}
else
{
inConnectors.Add(Tuple.Create(inputNode, inputData));
node = newNodeWorkspace.AddNode<Symbol>();
node.InputSymbol = inputReceiverNode.InPortData[inputReceiverData].NickName;
node.SetNickNameFromAttribute();
node.DisableReporting();
node.X = 0;
node.Y = inputIndex*(50 + node.Height);
uniqueInputSenders[key] = node;
}
var curriedNode = curriedNodeArgs.FirstOrDefault(x => x.OuterNode == inputNode);
if (curriedNode == null)
{
newNodeWorkspace.AddConnection(
node,
inputReceiverNode,
0,
inputReceiverData);
}
else
{
//Connect it to the applier
newNodeWorkspace.AddConnection(node, curriedNode.InnerNode, 0, 0);
//Connect applier to the inner input receive
newNodeWorkspace.AddConnection(
curriedNode.InnerNode,
inputReceiverNode,
0,
inputReceiverData);
}
}
#endregion
#region Process outputs
//List of all inner nodes to connect an output. Unique.
var outportList = new List<Tuple<NodeModel, int>>();
var outConnectors = new List<Tuple<NodeModel, int, int>>();
int i = 0;
if (outputs.Any())
{
foreach (var output in outputs)
{
if (
outportList.All(
x => !(x.Item1 == output.Item1 && x.Item2 == output.Item2)))
{
NodeModel outputSenderNode = output.Item1;
int outputSenderData = output.Item2;
NodeModel outputReceiverNode = output.Item3.Item2;
if (curriedNodeArgs.Any(x => x.OuterNode == outputReceiverNode))
continue;
outportList.Add(Tuple.Create(outputSenderNode, outputSenderData));
//Create Symbol Node
var node = newNodeWorkspace.AddNode<Output>();
node.Symbol = outputSenderNode.OutPortData[outputSenderData].NickName;
node.SetNickNameFromAttribute();
node.DisableReporting();
node.X = rightMost + 75 - leftShift;
node.Y = i*(50 + node.Height);
newNodeWorkspace.AddConnection(
outputSenderNode,
node,
outputSenderData,
0);
i++;
}
}
//Connect outputs to new node
foreach (var output in outputs)
{
//Node to be connected to in CurrentWorkspace
NodeModel outputSenderNode = output.Item1;
//Port to be connected to on outPutNode_outer
int outputSenderData = output.Item2;
int outputReceiverData = output.Item3.Item1;
NodeModel outputReceiverNode = output.Item3.Item2;
var curriedNode =
curriedNodeArgs.FirstOrDefault(x => x.OuterNode == outputReceiverNode);
if (curriedNode == null)
{
// we create the connectors in the current space later
outConnectors.Add(
Tuple.Create(
outputReceiverNode,
outportList.FindIndex(
x =>
x.Item1 == outputSenderNode
&& x.Item2 == outputSenderData),
outputReceiverData));
}
else
{
int targetPort =
curriedNode.Inputs.First(
x => x.InnerNodeInputSender == outputSenderNode)
.OuterNodeInPortData;
int targetPortIndex =
curriedNode.OuterNodePortDataList.IndexOf(targetPort);
//Connect it (new dynConnector)
newNodeWorkspace.AddConnection(
outputSenderNode,
curriedNode.InnerNode,
outputSenderData,
targetPortIndex + 1);
}
}
}
else
{
foreach (var hanging in
selectedNodeSet.SelectMany(
node =>
Enumerable.Range(0, node.OutPortData.Count)
.Where(port => !node.HasOutput(port))
.Select(port => new { node, port })).Distinct())
{
//Create Symbol Node
var node = newNodeWorkspace.AddNode<Output>();
node.Symbol = hanging.node.OutPortData[hanging.port].NickName;
node.SetNickNameFromAttribute();
//store the element in the elements list
node.DisableReporting();
node.X = rightMost + 75 - leftShift;
node.Y = i*(50 + node.Height);
newNodeWorkspace.AddConnection(hanging.node, node, hanging.port, 0);
i++;
}
}
#endregion
// save and load the definition from file
newNodeDefinition.SyncWithWorkspace(dynamoModel, true, true);
dynamoModel.Workspaces.Add(newNodeWorkspace);
string name = newNodeDefinition.FunctionId.ToString();
var collapsedNode = currentWorkspace.AddNode(avgX, avgY, name);
undoRecorder.RecordCreationForUndo(collapsedNode);
// place the node as intended, not centered
collapsedNode.X = avgX;
collapsedNode.Y = avgY;
collapsedNode.DisableReporting();
foreach (
var nodeTuple in
inConnectors.Select(
(x, idx) => new { node = x.Item1, from = x.Item2, to = idx }))
{
var conn = currentWorkspace.AddConnection(
nodeTuple.node,
collapsedNode,
nodeTuple.from,
nodeTuple.to);
if (conn != null)
{
undoRecorder.RecordCreationForUndo(conn);
}
}
foreach (var nodeTuple in outConnectors)
{
var conn = currentWorkspace.AddConnection(
collapsedNode,
nodeTuple.Item1,
nodeTuple.Item2,
nodeTuple.Item3);
if (conn != null)
{
undoRecorder.RecordCreationForUndo(conn);
}
}
collapsedNode.EnableReporting();
currentWorkspace.EnableReporting();
foreach (var node in newNodeWorkspace.Nodes)
node.EnableReporting();
newNodeWorkspace.WatchChanges = true;
}
}