Script Example Analysis in Altium Designer
To provide further insight into the general aspects of the Scripting System, and the use of Delphi and X2 Object Models in scripts, two example projects are examined here from a functionality perspective – a board outline copier and a netlist generating script.
The Board Outline Copier and Netlister scripts are developed using the X2 Object Models to illustrate the capabilities of the scripting system in Altium Designer. These are existing scripts available in the example script collection as follows:
- The Board Outline Copier script utilizes the PCB Object Model to copy the existing PCB board outline as tracks and arcs onto a specified layer.
See\Scripts\VB Scripts\CopyBoardOutlinePRJ.PRJSCR
. - The Netlist generator script utilizes the WorkSpace Manager Object Model to generate a netlist in the traditional Protel (v1 and v2) format.
See\Scripts\Delphiscript Scripts\WSM\Protel Netlister\ScripterProtelNetlist.PRJSCR
.
Board Outline Copier Project
The aim of the Board Outline Copier is to copy an existing board outline from the PCB document to a different layer in the same document.
The project uses a Script Form so the user can interact with a dialog to nominate the width of the board outline and select its target layer from a drop-down menu. Using the PCB Object model and its PCB interfaces from the PCB API, the objects of a board outline are extracted and copied onto the specified layer.
The main parts of the script are:
- A global
PCB_Board
(ofIPCB_Board
type) variable. - A
CopyBoardOutline
subroutine that acceptsAWidth
andALayer
parameters. - The
bOkClick
event handler which obtains the width and layer values from the script form and then executes theCopyBoardOutline
subroutine. - The
bCancelClick
event handler which closes the Board Outline script form (dialog).
Script functionality
The script uses a script Form that needs event handlers to capture the mouse clicks of individual controls such as the OK and Cancel buttons.
The OK button event handler is essentially as below:
Sub bOKClick(Sender) Dim Width Dim Layer Call StringToCoordUnit(eWidth.Text,Width,PCB_Board.DisplayUnit) Layer = String2Layer(cbLayers.Items(cbLayers.ItemIndex)) End Sub
Here, the form's mouse OnClick event handler (bOKClick
) uses the the StringToCoordUnit
function to obtain the entered width of the outline (the eWidth
string from the TEdit box) in internal coordinate values. This function applies the current board units (PCB_Board.DisplayUnit
property) to the Width
variable.
Similarly, the selected layer string (the cbLayers
item from the form TComboBox) is passed to the String2Layer
function to obtain an enumerated value for the Layer
variable. Note that in this project the form's TComboBox is pre-populated with an indexed list of layer strings (cbLayers.Items
) – see the Form's CopyBoardOutlineForm.dfm
file for the layer list.
The final step in the event handler (bOKClick
) calls the CopyBoardOutline
subroutine with the Width
and Layer
variables as passed parameters. The handler for the form's Cancel button (bCancelClick
) simply closes the form.
IPCB_Board Interface
Within the OK button handler (bOKClick
), the current board is obtained from the IPCB_Board
interface through the IPCB_ServerInterface
returned by the special PCBServer
function. Here, the GetCurrentPCB
function sets the current board reference to the PCB_Board
variable.
The current board outline (IPC_BoardOutline
) then is obtained throughout the script from the IPCB_Board
interface BoardOutline
property, using the above PCB_Board
board reference.
The board outline needs to be initialized before proceeding with copying and creating a new outline. An outline – represented by the IPCB_BoardOutline
interface – can be initialized using the interface's rebuilding/validation methods.
PCB_Board.BoardOutline.Invalidate PCB_Board.BoardOutline.Rebuild PCB_Board.BoardOutline.Validate
Outline Arc and Track segments
The IPCB_BoardOutline
interface, representing the board outline, is inherited from the IPCB_Group
interface. An IPCB_Group
interface represents a group object that can store child objects. An example of an IPCB_Group
interface is a polygon or a board outline, since these can store arcs and tracks as child objects.
A board outline object stores two different type of segments – ePolySegmentLine
and ePolySegmentArc
which represent a track or arc object respectively. The number of segments is determined by the PointCount
property from the IPCB_BoardOutline
interface, which extracts each outline vertex to the I
variable for the For-To-Next
loop.
Each segment of the obtained board outline is checked for tracks and arcs with the If PCB_Board.BoardOutline.Segments(I).Kind = ePolySegmentLine Then
statement. If not a track segment (ePolySegmentLine
) the Else
part of the statement assumes the segment is an arc.
For each segment found and depending on the segment type, a new track or arc object is created using the PCBObjectFactory
function.
PCBObjectFactory Function
Creating the new PCB objects employs the PCBObjectFactory
function directly from the IPCB_ServerInterface
interface.
'Create new Track object PCBServer.PCBObjectFactory(eTrackObject, eNoDimension, eCreate_Default) 'Create new Arc object PCBServer.PCBObjectFactory(eArcObject, eNoDimension, eCreate_Default)
The PCBObjectFactory
function parameters set the object type (Track, Arc, Via etc), the dimension kind (Linear, Radial etc) and the object creation mode (to a local default or global preferences).
After each track or arc object is created by the PCBObjectFactory
procedure, its properties are instantiated by the track/arc statements that follow.
The Track and Arc properties are represented by their respective interfaces, IPCB_Track
and IPCB_Arc
, where the relevant properties are implemented by the script. For example, the new track coordinates are obtained from the source outline segment vertices, where Track.X1
and Track.Y1
represent the track's initial coordinates and the X2
and Y2
properties are its final coordinates.
Track.X1 = PCB_Board.BoardOutline.Segments(I).vx Track.Y1 = PCB_Board.BoardOutline.Segments(I).vy Track.X2 = PCB_Board.BoardOutline.Segments(J).vx Track.Y2 = PCB_Board.BoardOutline.Segments(J).vy Track.Layer = ALayer Track.Width = AWidth
As can also be seen in the above code snippet, the track Layer and Width properties are simply defined by the passed values extracted from the user interface dialog – the Form's cbLayers
and eWidth
variables.
Once fully defined, the new objects are added to a specified layer of the PCB document with the PCB_Board.AddPCBObject(NewObject)
statement, where NewObject
here is Track or Arc.
PreProcess and PostProcess
When creating a PCB object, the PreProcess
method from the IPCB_ServerInterface
object interface needs to be first invoked to ready the PCB server. After the object creation, the PostPocess
method (also from the IPCB_ServerInterface
interface) is applied to inform the server that the object additions are complete.
The PreProcess
and PostProcess
methods keep the Undo system and other subsystems of the PCB editor up to date and in synchronization. Below is a representative code snippet with the PreProcess
and PostProcess
statements.
PCBServer.PreProcess 'Create PCB objects PCBServer.PostProcess
When objects are added to a nominated layer that has not been displayed in the PCB document, the layer needs to be forced to be visible. This is handled by the PCB_Board.LayerIsDisplayed(ALayer) = True
statement, where ALayer
is the user selected layer.
Document Refresh
Lastly, the PCB document with its new board outline is refreshed by the PCB:Zoom
command and its associated Action = Redraw
parameters. The zoom command parameters are applied using the AddStringParameter
procedure after the parameter buffer is first cleared with the ResetParameters
method.
Netlister Project
The aim of this Netlister script project is to generate a standard Protel netlist (in either Version 1 or Version 2 formats) for an Altium Designer project containing schematics. A flat netlist of a schematic project is separated into two sections:
- Component designators and the information associated with each component,
- Net names and the information associated with each net name, along with pin connections (pins of a component).
The API's WorkSpace Manager Object Model provides interfaces that represent the project and its constituents – the documents, the components and its pins, and the nets. The WorkSpace Manager is a system server coupled tightly with the Client module that deals with projects and their associated documents. It provides compiling, multi sheet design support, connectivity navigation tools, multi-channel support, multiple implementation documents, and so on. To retrieve the WorkSpace Manager interface, invoke the GetWorkspace
function which yields the IWorkspace
interface.
For the Netlister script the interfaces of interest are the IWorkSpace
, IProject
, IDocument
, IComponent
and INet
interfaces.
Note that some of the interfaces, especially the design object interfaces, correspond to equivalent Schematic Object interfaces. This is because the logical documents in a project are schematic documents with connectivity information. In fact the Schematic Object model can be used instead of the WorkSpace Manager, but the latter provides the functionality to compile a project and extract documents from a project, as well as retrieving data from schematic objects.
The main parts of Netlister the script are:
- A global
TargetFileName
string variable. which is the file name of the netlist. - A global Netlist
TStringList
collection object which is populated with the netlist data. - The
WriteComponent_Version1
andWriteComponent_Version2
procedures. - The
WriteNet_Version1
andWriteNet_Version2
procedures. - A
ConvertElectricToString
function which converts a pin's electrical property to a string - The
GenerateNetlist
procedure which manages the data generation and the filename, path and directory housekeeping tasks.
Script functionality
The two parameter-less procedures, GenerateProtelV1FormatNetlist
and GenerateProtelV2FormatNetlist
, will appear in the Select Item to Run dialog offering the choice of generating a Protel V1 format netlist or a Protel V2 format netlist. These procedures call the GenerateNetlist
procedure with the netlist format choice (0
or 1
) as a passed parameter.
Procedure GenerateProtelV1FormatNetlist; Var Version : Integer; Begin // Protel 1 Netlist format, pass 0 GenerateNetlist(0); End; Procedure GenerateProtelV2FormatNetlist; Var Version : Integer; Begin // Protel 2 Netlist format, pass 1 GenerateNetlist(1); End;
GenerateNetList
The GenerateNetList
procedure retrieves the workspace interface so that the project interface can be then extracted for the current project (IWorkspace.DM_FocusedProject
).
The project needs to be compiled before nets can be extracted, as the compile process builds the connectivity information of the project. The project interface's DM_Compile
method is applied (IProject.DM_Compile
) as shown in the code snippet below. Note that recent versions of Altium Designer compile projects automatically, so this step is optional.
WS := GetWorkspace; If WS = Nil Then Exit; Prj := WS.DM_FocusedProject; If Prj = Nil Then Exit; // Compile the project to fetch the connectivity info for design. Prj.DM_Compile;
The component and net information is stored in the Netlist object of the TStringList
type, which is used later to generate a formatted netlist text file. The TStringList
object is a Delphi class which is available to use in scripts.
The Generate
procedure is then called with passed parameters that define the current project path and filename, plus the netlist format version.
Generate
The Generate
procedure obtains the project path as the target output path for the generated netlist file (from the passed DocumentPath
parameter), determines the netlist file name (TargetFileName
) and checks the flattened status of the project (IProject.DM_DocumentFlattened
).
For all the schematic documents in a project, each document is then checked for nets and components with the WriteNets
and WriteComponents
procedures, and ultimately extracted to the Netlist
object.
Write Nets and Components
A netlist is composed of component and net sections, so two procedures are required to write component data and net data separately.
Only nets with greater than two nodes will be written to a netlist and those with less are discarded. For each net, the net name is based on the Net's DM_CalculatedNetName
method, which extracts the net names from the connectivity information of the compiled project.
Two code snippets for the Components and Nets sections of a netlist are shown below for Version 1 netlist format. Note that the component and net data are stored in the NetList
object, which is a TStringList
type. The generated netlist is composed of two sections; the component information section and the net information section.
Components section
In the WriteComponent
procedure each component found from the Project is checked if it is an actual component, and then the physical designator, footprint and part type values are extracted. These are added to the Netlist object container (NetList.Add
) to build the netlist itself.
If Component <> Nil Then Begin NetList.Add('['); NetList.Add(Component.DM_PhysicalDesignator); NetList.Add(Component.DM_FootPrint); NetList.Add(Component.DM_PartType); NetList.Add(''); NetList.Add(''); NetList.Add(''); NetList.Add(']'); End;
Nets section
For the Nets procedure, the NetName and the Designators are extracted if a net has two or more Pins (INet.DM_PinCount
). The net and pin information plus formatting characters are added to the Netlist
container to build the netlist. The below snippet is the net writing procedure for the version 1 netlist.
If Net.DM_PinCount >= 2 Then Begin NetList.Add('('); NetList.Add(Net.DM_CalculatedNetName); For i := 0 To Net.DM_PinCount – 1 Do Begin Pin := Net.DM_Pins(i); PinDsgn := Pin.DM_PhysicalPartDesignator; PinNo := Pin.DM_PinNumber; NetList.Add(PinDsgn + '-' + PinNo); End; NetList.Add(')'); End;
Note that the more verbose netlist format, Protel v2, includes the electrical properties for net pins (In
, Out
, Passive
, HiZ
etc).
The net writing procedure for the version 2 format (WriteNet_Version2
) therefore interrogates each net pin's electrical property (INet.DM_Electical
), which is then converted by the called ConvertElectricToString
procedure – essentially a string conversion lookup table. These are then added to a local string variable (ElectricalString
), which is in turn added to the Netlist container object.
Create Netlist file
Finally with the Netlist
container object fully populated with the project component and net information, in the chosen format, the Generate
prodedure writes the Netlist
data to a file (TStringList.SaveToFile
). The file path and name are defined by the TargetFileName
string variable, as determined in the Generate
procedure.