CHIPNDALE 0.20
FOR INTERNAL XEROX USE ONLY
ChipNDale
An interactive editor for VLSI designs
MOS Designer's introduction
Release 0.20
Ch. Jacobi, Kim Rachmeler (May 14, 1985)
Filed on: [Indigo]<ChipNDale>Documentation>Chipndale20.tioga
© Copyright 1983, 1985 Xerox Corporation. All rights reserved.
Abstract: ChipNDale is an interactive graphic layout tool made to run in Cedar. This document is an introductory reference for users creating or editing VLSI designs; there will be other documentation describing additional utilities like creating checkplots, masks, or CIF output, and doing design rule checking. Programmers who want to access ChipNDale from a program should read the additional documentation available for these purposes.
XEROX   Xerox Corporation
    Palo Alto Research Center
    3333 Coyote Hill Road
    Palo Alto, California 94304

For Internal Xerox Use Only
0. Introduction
0.1. History
Chipndale1 is the ultimate interactive VLSI layout editor written in Cedar. It is normally used interactively, but all its operations can be accessed by other programs.
In early design stages called Chipmonk II, ChipNDale is the Cedar successor to Chipmonk, an interactive layout editor written for the Alto world. But although ChipNDale looks a good deal like Chipmonk, there are quite distinct dissimilarities. Like Chipmonk, combinations of keyboard and mouse commands allow creation and modification of both primitive (contacts, transistors) and constructed (cells) objects. Multiple views of a design are available on both the color and B&W displays. ChipNDale can read in old Chipmonk files and some ChipNDale designs can be written out in Chipmonk format. Unlike Chipmonk, ChipNDale incorporates the concept of "technology independence", the idea that separate technologies (NMOS, CMOS, PC boards, etc.) do not interfere with the basic ChipNDale kernel, nor do they interfere with one another. New technologies may be created with their own definitions of commands and structures, allowing ChipNDale to expand to accommodate new methods and applications.
There are three main sections to the ChipNDale documentation. The first is the user's manual, the file you are currently reading. The second is a guide to the additional tools that can be loaded along with ChipNDale; this document can be found in the file ChipndaleTools20.tioga. The third section is a set of hints for programmers of ChipNDale clients; this file can be found under ChipndalePrograms.tioga.
The rest of this introduction will provide you with step-by-step information to start ChipNDale and read in design files. The rest of the document is intended as a reference manual; use the "Levels" button to scan the document for the general section you are interested in reading. The amount of descriptive detail increases with the number of visible levels. The notes in small print at the deepest nested level are usually examples or explanations that the inexperienced user might need. The "Find" button can also be useful if you are searching for a particular topic.
1 The name ChipNDale comes from neither the fine furniture in England nor the fine figures in LA but from Chip 'n Dale, the two furry characters created by Walt Disney (two chipmunks -- Chipmonk II, get it?) Subnote: "Chipmonk II" also referred to the split between a technology independent kernel and all the add-ons, technologies and commands.
0.2. How to start
Installing the program
Bringover /indigo/chipndale/5.2/top/cddesign20.df
It is usually best to create a separate subdirectory for ChipNDale; this allows you to remove it easily when you want to upgrade to a new version. This DF file will equip the machine with all the information it needs to run the NMOS, CMOS, and ChipNSil versions of ChipNDale.
ChipNDale needs a Dorado to run reasonably fast. The current version runs on top of Cedar 5.2.
Start the program
To start up a session of ChipNDale (in the same subdirectory containing its files) you can use the following load files:
% CDCMos or
%
CDNMos or
% CDSil
These load files will load the ChipNDale program and create a Terminal monitor viewer (hereafter referred to as "Terminal"). Terminal keeps a log of all the commands issued concerning ChipNDale; it is where you will look to find information about what ChipNDale is trying to execute and how that execution is progressing. Some technologies might have load files which make the start with commandfiles superfluous, however, using the commandfiles might be faster.

When you use ChipNDale for the first time, just go ahead. Playing with ChipNDale is not dangerous: when ChipNDale reads in an existing design it will not overwrite the file unless you explicitly issue an output command. Then it asks you for a file name first, before doing any actual output. When you are an old Chipmonk user: ChipNDale is able to read in Chipmonk files; look in the documentation about additional tools.
Get a design to work with
To get an existing design up on the screen, use
% CDRead <optional name of a ChipNDale design file>
ChipNDale design files contain the technology of their design; However, the code handling that technology must be loaded before issuing the CDRead command. If no filename was given to the read command, Terminal will respond with the request to type a file name in. The file may either be present locally or on one of the file servers; default extension is ".dale". You do not need to type in the extension.
To start up a fresh design use one of the commands:
% CDNewCMOS or
%
CDNewNMOS or
%
CDNewSil

These commands will display the design (or new viewer) on the screen.
1. General Definitions and Descriptions
1.1. The Terminal
The Terminal viewer is one of the main communication points between the user and ChipNDale. Terminal not only keeps a log of commands executed but also prompts the user for input and displays error messages. There is only one Terminal for any invocation of ChipNDale, regardless of the number of designs displayed.
1.2. Technologies
One of ChipNDale's main features is its ability to adapt to new technologies without changes to the core of the program. This feature is called "technology independence"; it means that new fabrication techniques or applications can be described in modules and plugged into the existing system. But this capability also means that the user must make sure that the appropriate technology is loaded so that ChipNDale can access features unique to that technology. For MOS designs, ChipNDale distinguishes between the NMOS and the CMOS technology.
1.3. Design
A design is what a designer creates; it is the unit used to be stored in files, and also the unit used in the synchronization. Every design is in a particular technology and consists of some geometry and a directory. The design is also the unit which is put into one file usually.
1.4. Objects
Primitive objects are the "atoms", if you will, of the ChipNDale world. The existing primitives are transistors (straight and angle), contacts (buried and butting), and wires.
Composite objects are cells, repetitions or imports. These are the building blocks of the more complex structures used to construct designs. All the composite objects must be listed in the design's directory. Cells are the most basic building blocks.
The types of objects which can be included in a design are specified by the technology. However some types of objects, cells and rectangles, exist in all technologies.
1.5. Additional Tools
ChipNDale makes it easy to write additional tools, causing a large variety of extra utilities to spring up around the core program. It is not possible to describe all additional tools in this document; you can find that description in ChipndaleTools20.tioga. The list of additional tools starts with "design rule checking", "making checkplots", "cif generation", "mask generation"...
1.6. Tip Tables
Often used as the real truth of the user interface, users are invited to browse the tip table. The tiptable is alphabetically sorted and it has comments. ChipNDale typically uses two tiptables, one which describes the general ChipNDale user interface, and a second one which describes the technology dependent commands.
2. Commands
2.0. In General
ChipNDale commands are grouped such that those most frequently applied use the lefthand side of the keyboard. This grouping allows easy finger placement without having to move your right hand away from the mouse. This speedy access, however, has outweighed mnemonics, which is why "Q" draws a transistor, not "T". Infrequently used commands have been shuffled off to the righthand side of the keyboard. Commands are executed in the ChipNDale viewer with the input focus. If the viewer does not have the input focus, the cursor will appear as a fat arrow pointing down. Click any mouse button to obtain the proper cursor.
The mouse buttons are ordered such that the middle button controls drawing objects, the left and right buttons control modifications. Drawing only occurs when the middle button is pressed or held down; alterations only occur when the left or right button goes up.
Most commands that affect selected objects can be performed with either the left or the right button, or with the CTRL key; the left button only affects the object pointed to, the right button or CTRL applies all currently selected objects. These commands are indicated in the documentation with the choice {Left or Right or CTRL}, meaning that the command will be applied to a different set of objects depending on the button used. The CTRL key can be applied only to execute those commands which do not depend on a mouse position.
The following commands refer to the default CMOS or NMOS ChipNDale tip table.
2.1. The Pop-up menus and the control panel
Pop up menus
ChipNDale has real many commands, more than you are willing to remember. Pop up menus allow you to call commands, without having to know lots of exotic key combinations. There are many pop up menus available, and the menus can get additional entries when more programs are loaded. You can always try what commands a pop up menu has; mouse clicking outside of it discards the menu. To get a pop up menu, push the space key together with its letter key.
<G>-<Space> the global menu; mainly allows call of other menus
<C->-<Space> the cell menu; creation etc of cell
<D->-<Space> the directory menu; get an object, clean the directory...
<I or O>- <Space> the IO menu
<P>-<Space> the program menu; call of additional programs.
<T>-<Space> the transformation menu; mirror and rotate
<N>-<Space> the names and properties menu
<V>-<Space> the viewer menu
<B>-<Space>  the color display menu
<S>-<Space> the special commands menu
<M>-<Space> the draw mode menu
<,>-<Space>  the simplification menu
<.>-<Space>  the ticks menu
</>-<Space> the grid menu
Some few pop up menus are reserved for commands which need a position as parameter, these commands obviously need a mouse interaction to to make the pop up menu appear.

<P>-<SHIFT>-Middle 
another program menu; programs executed on a rectangular area
<H>-<Middle> the hard copy menu; the called hard copy programs do all want a
   rectangular area as input parameter.
Note: the pop-up menus can be altered dynamically by client modules while ChipNDale is already running; The general documentation can not accurately document all entries, but contains the most important entries .
Control panel commands
The control panel is a graphical method of changing layout parameters. Every design has a control panel associated with it; The control panel allows the designer to select default values, mainly the layer in which he wants to draw, but also some other modes. The panels also have some technology dependent entries.
General Commands:
Control panel commands are executed by clicking mouse buttons on top of the text (not the value).
Left:  increment value
Right:  decrement value
CTRL Left:  double value
CTRL Right:  half value
Middle:  (when done over a layer description)
  selects this layer as default for drawing wires
<SHIFT>-
<mouse key>: shows a pop up menu, allows entry of arbitrary values.

The control panel can also be scrolled. The 'split viewer' command allows the user to create a viewer on the associated design if all other viewers on that design have been destroyed.
Technology dependent commands:
There are several buttons on the panel referring to modifications to transistors. Both NMOS and CMOS panels have width and length buttons for changing the default measurements in the horizontal and vertical dimensions respectively. The NMOS panel has three additional buttons. The 'implant' button changes the type of transistor according to the following codes:
NMOS transistor codes
weak allows access to weak implants, a feature which you probably don't want to use.
implant if weak is 0
0: enhancement mode
1: depletion mode
implant if weak is 1
0: 0 threshold
1: weak depletion
The other two extra buttons change the width and length of pull-up transistors.
2.1. Simple Selection
Select Single Object
Left Point to desired object and hit the Left mouse button. All previous selections will be removed and this object will be selected. (Note: just the condition of being selected is removed, not the object itself!)
Fine point: If the mouse position is exactly the same as before, and no other key is pressed, the selection will rotate through the possible objects at that point; otherwise the command will reselect the last selected object under the mouse position. This enables you to select objects completely obscured by other overlaying structures.
Select Multiple Objects
Right Selections made with the Right mouse button will be added to the collection of previously selected items.
Deselect Object
<ESC>-Right Point to a selected object, hold down <ESC> and hit Right. Selection will be removed.
Fine point: <ESC>-Left will deselect all objects.
Change selection
<SPACE> If you are selecting an object but have not yet let the mouse button up, you can change your choice by keeping the button down, moving the mouse to the new object and hitting <SPACE>. This change in midstream will also work even if you are about to execute a command on the selected object.
For example: Say you want to rotate something. You press R, point to the appropriate object and press the Left mouse button. As soon as you let the button up, the command will be executed. But wait! You really wanted the object just to the right! No problem. Keep the mouse button and the R down, move the cursor to the new object, and hit <SPACE>. The selection will be switched to the new pointed objected. Now when the mouse button is released, the new object will be rotated (either in place of or in addition to the old object, depending upon whether the Left or Right mouse button was used).
2.2. More Advanced Selection <<***>>
Area Select/Deselect
There are two ways to handle area selections, the common area selection selects (or deselects) all objects which are completely included in a rectangular area. Use the common selection commands, but drag the mouse while the button is down.
The other method of area selection handles every object which touches the designated area.
<SWAT>-Left    other area select
<SWAT>-<right-SHIFT>-Left other area de select
Select All
<ESC>-<SPACE> selects everything in the current design
Select Entire Layer
<ESC>-<SHIFT>-{Right or Left} all of the objects belonging to the current layer will be selected or added to the selection.
2.3. Drawing objects
Wires
Middle Pressing the Middle button and moving the mouse draws a wire of the current layer with the current width, releasing the button confirms the position and length of the wire.
<SHIFT> Hitting <SHIFT> while drawing a wire draws the first segment of the outlined wire.
<SPACE> Hitting <SPACE> while drawing a wire flips the orientation of the direction the wire bends.
<ESC> Stops the wire drawing process.
Note: The current layer can be changed with either the keyboard or the control panel, the width can be set only through the control panel.
Choosing a layer
All the layer commands use keys in the top row.
<ESC>-Middle Clicking the middle button while holding down <ESC> will set the current layer to be the same as the layer of a pointed object, if it has a unique layer.
Change layer by hitting the associated layer number key. The control panel can also be used to change layers; note that the order of the layers associated with the keys is the same as the order listed in the control panel.
CMOS
<1> diffusion:
  default N+, with <SHIFT> P+
<2> poly
<3> metal
<4> diffusion contact:
  default P+ to N-well, with <SHIFT> N+ to P-well
<5> N-well
<6> 2nd layer metal
In general, if the <SHIFT> or <LOCK> key is down, everything is done in the P-diffusion world; <LOCK> up indicates N-diffusion. You can change between pdif and ndif just by switching the position of the <LOCK> key without hitting <1>.
Note: NMOS uses <4> for 2nd layer metal, it has no wells or well contacts.
Transistors
Q-middle Draw a n-transistor (with SHIFT or LOCK: a p-transistor)
W-middle Draw an angle n-transistor(with SHIFT or LOCK: an angle p-transistor)
Contacts
Contact commands use the same keyboard keys as the layer commands plus the middle mouse button; the contact is made between the indicated layer and metal. The command is executed by holding down the appropriate numeric keys while hitting the middle button.
Middle mouse button while:
<1> N+ to metal, with <SHIFT>: P+ to metal
<2> poly to metal
<3> Butting P+ to poly and metal; with <SHIFT>: N+
<4> P+ to substrate, with <SHIFT>: N+ to N-well
<6> metal to metal 2
<1>-<2> Buried N+ to poly; (There are no P+ buried contacts)
<1>-<2>-<3> Butting P+ to poly and metal; with <SHIFT>: N+
This command is supposed to remind you of the three layers used in a butting contact; everybody will probably use the simpler <3>-Middle command though. I know I would.
Note: NMOS uses <4> for 2nd layer metal, therefore <4> for a metal to metal 2 contact; there are no substrate contacts.
Drawing objects by name (from the directory)
C-Middle Draw object, placing origin at current cursor position. Terminal will prompt for name of the object to be drawn.
2.4. Simple transformations
Move by a vector
<CTRL>-{Left or Right} Move selected object(s).
If done with the right button, moves entire collection of selected objects relative to the former cursor position as indicated by the vector drawn on the screen when moving the mouse. The left button reselect a single object and moves only this object.
Move an incremental step
A-{Left or Right or CTRL} to the left.
S-{Left or Right or CTRL} to the right
W-{Left or Right or CTRL} up
Z-{Left or Right or CTRL} down
Note that the four keys A S W and Z are arranged in the same relative positions as the directions they move the selected object(s). The size of the step can be set by the control panel.
Copy
<SHIFT>-{Left or Right} Copy selected objects positioned according to the drawn vector; the simple copy is similar to a move save for an additional <TAB> -- however, the step moves do not have a corresponding copy version; they would not make sense.
If done with the right button, copies entire collection of selected objects by choosing an origin with the left mouse button, holding that button down, and moving the cursor to the desired destination. The left button only copies the single selected object.
Rotate and mirror
R-{Left or Right or CTRL} Rotate selected object(s) by 90 in a clockwise direction, the bottom left corner remains fixed.
T-{Left or Right or CTRL} Mirror selected object(s) across the vertical axis
E-{Left or Right or CTRL} Mirror selected object(s) across the horizontal axis
Note that rotation and mirroring can also be done with the Transform pop-up menu, <SPACE>-T.
Rotation is the R command; for mirroring E and T were selected because they are located next to the "R" (rotate) key and have symmetries appropriate to their function.
Delete
D-{Left or Right or CTRL} Delete selected object(s)
Un-Delete
D-ESC Undelete last deleted object(s)
2.5. Stretching objects
Stretch
{A, S, W, Z or none}-<TAB>-{Left or Right} Note that stretching is very similar to the moves; instead of moving the object, only the pointed border is moved, the object is stretched. Therefore, the stretch commands are identical to the move commands except, that a modifier key, <CTRL> is used. The letter A, S, W, Z or Q specify the direction and the amount, as in the moves.
You must be pointing to an edge of a selected object each time the mouse button is pushed. The pointed edge will be stretched.
For now, angle transistors stretch in a crazy way, please be forgiving.
Grow/Shrink
G-{Left or Right} Stretch pointed side of object(s) one lambda out, i.e. grow object in given direction
F-{Left or Right} Stretch pointed side of object(s) one lambda in, i.e. shrink object in given direction
You must be pointing to an edge of a selected object each time the mouse button is pushed. The pointed edge will be stretched.
2.6. Some exotic but useful or necessary commands <<***>>
Stretchy move
{<TAB>-<CTRL>-A, S, W, Z}
{<TAB>-<CTRL>}-{Left or Right}

Stretchy move is a special move which maintaining primitive connectivity; The commands are like the moves, except the TAB modifier key.
Stretchy move is implemented in a strictly geometric way and does not understand the electrical behavior... be gentle on imperfection.
Measuring distance, counting objects, information about an object
<CTRL>-Middle
-- Click the middle key quick when <CTRL> is down: you get information about the selected objects.
-- Draw a vector by holding down <CTRL> and the middle button while moving the mouse. When the mouse button is released, Terminal will display the values of the end coordinates and the distance between them.
Yes, these two commands use the same keys, only the time scale is different.
Split a wire
|-{Left or Right} Split wire(s) along its/their width by holding down both the "|" key and the appropriate button while moving the mouse. Command is executed by lifting the mouse button.
Interrupt the drawing
<ESC>-<LF> Hold down a few seconds! Interrupts the drawing, of all viewers, immediately after the command is accepted
Abort a command
<ESC>-<DEL> Aborts the current command; works at least if the implementation of the current command is kosher and asks for the abort flag... . Of course, short commands do not ask the flag, but the abort command at least flushes the command queue.
An analogue is using <DEL> to abort an input on Terminal.
Special commands menu
<Space>-S The special commands menu is a catch-all menu for odd commands which don't really fit in elsewhere. It includes commands such as undelete, abort command, and statistics, among others.
2.7. Viewer commands
Change scale
"<", ">" Hitting <<> decreases magnification; hitting <>> increases it. It is easier to remember these commands by looking at the upper case options on the keys, but of course the real keys are <.> and <,>.
Or, if you want to be visual in remembering the commands, note that the "<" starts small then gets bigger, hence it makes objects appear bigger. In the same way, ">" starts big and ends small, making objects appear smaller.
Change position, pan viewer
<SPACE>-Middle Moving the mouse while holding down both the <SPACE> key and the middle button draws a vector on the screen. The view of the design will be moved in proportion to that vector when the mouse button is released.
Show a particular area, zoom in viewer
<SPACE>-Left
<SPACE>-<SHIFT>-Left Drag a box to define an area. The view of the design will be scaled and moved such that this box will be displayed. This displays the drawn area on the viewer; together with SHIFT it choses another viewer.
Show position of other viewers <<***>>
<V>-Middle Shows the positions of the other viewers.
View top cell <<***>>
<SPACE>-<TAB> Cause the viewer position and scale to change so that all objects of the top pushed cell are visible on the screen.
View all selections <<***>>
<SPACE>—<CTRL> Cause the viewer position and scale to change so that all selected objects are visible on the screen.
2.8. Cells
Note that these commands can also be accessed through the cell pop-up menu, <SPACE>-C. Drawing cells is not a special command but like putting down any named object which is in the directory: use the C-Middle command.
Create cell
X-C-Middle Create a new cell from the set of all selected objects. Terminal will prompt for a unique cell name.
Expand (Flatten) cell
Use the cell pop up menu.
Push-Pop
C-{Left or Right or CTRL} Push into cell: the rest of the design will be grayed.
C-<SHIFT> Pop out of cell
Directory
<SPACE>-D
Directory pop-up menu:
list restricted: list explicitely named objects
list all direcory: list complete contents of directory
clean up restricted: list unused entries created by programs, and ask whether they should be removed from the directory.
clean up directory: list all unused entries, and ask whether they should be removed from the directory.
remove ob: remove a particular entry from directory, (checked, only unused entries can be removed)
replace ob: replace a perticular object in the whole design
rename selected ob: rename selected object in directory
list imports: list names of imported designs
list importee's ob: list referenced object of a particular imported design
CELLS: calls Cells pop-up menu
Although the directory contains mostly cells, there are other object classes stored there as well.
2.9. IO, Imports, and Includes
IO
The IO menu allows operations on designs which already have a viewer; use the CommandTool commands to read in the files originally.
<SPACE>-I or <SPACE>-O
Use the IO pop-up menu. Default extension is .dale.
Chipmonk compatible files:
The IO pop-up menu allows to create backwards compatible chipmonk output. (.chip file). This command is restricted to CMOS and NMOS IC designs. Try to avoid switching between the chipmonk and chipndale worlds frequently; on every transfer you may loose some information. Not all ChipNDale features can be written onto Chipmonk compatible files. Not all Chipmonk representation of objects can be represented in chipndale, mainly those which can not be fabricated safely are excluded.
Imports
X-Middle Draw an imported object. The command queries for the design, and then for the object. A reference to this object is drawn.
To import a design means to make references to objects from the imported design. The imported objects are not included in the importing design but only referenced. If objects are changed in the original (imported) design, and this design then re-loaded, the changes made are propagated to our importing design.
To draw imported objects it is first necessary to load the design we are importing from using the IO menu. Once the design is loaded, we can import any of its objects.
There is an easier way to draw imports: Open a viewer on the design which is used as source; make this design the selected design X-<SPACE>-Right (this means we remember this design as selected design; it does not mean that its objects are selected). Select an object in the source design. To draw this object in your design, use X-<SPACE>-Middle. Again, the design we are importing from must be loaded first.
Once a reference to an imported object is made, it is possible to really include that object in the current cell directory. It is then no longer referenced but a part of the new design: use the "merge in" entry in the directory menu.
Include
To include a design means to make all objects of that directory local. Use the IO menu to do includes, but usually one would prefer to import a design.
2.10. Repetitions
Description
A repetition is a set of objects placed at regular intervals along a given vector a given number of times. This feature allows the designer to create uniform structures quickly and easily. Any group of objects can be used as the basis for a repetition, even repetitions themselves.
Commands
=-Middle (note the repeated horizontal lines)
Make a repetition of the selected objects
Select the objects you want to form the basic unit of the repetition. Hold down "=" and draw a vector with the middle button. The vector indicates the spacing of the units. The vector is pointing to the position of the origin of the next unit, where the origin of any unit is defined by the tail of the vector. After the middle button is lifted, Terminal will prompt for the number of units you want in the repetition.
[-{Left or Right}
Increment count on selected objects (repetitions)
]-{Left or Right} (note that "[" and"]" are just below "=")
Decrement count on selected objects (repetitions)
=-<Shift>-Middle
Change the repetition vector of the selected repetition.
Any repeated object has the possibility to ask what index it has in the repetition. It is possible to change a repeated object into a cell; however there is no way back.
2.11. Properties, Signal Names
Names and Properties Menu
It is possible to hang arbitrary properties to any application of objects. These properties may or may not affect any program's behavior, or may only be comments for designers. Programs can protect their properties from designers, so the property mechanism can be used without danger of contention.
<Space>-N The names and properties menu
P-Left Shows all the properties of the selected application on terminal
P-Middle Asks for a property name and allows to replace the value of the property. Properties included interactively cannot make use of all the nice Cedar types, however, a pop-up menu allows you to select the types of the property value in some limited range. Preferred types for properties are Rope.ROPE, ATOM and REF INT. The name of a property is always converted to an ATOM.
Properties using these types are saved while a design is written on a file and read back. However, clientprograms may affect this and force a different behavior for properties they own. Such properties are usually reserved by the implementor for his/her exclusive use so designers will not be surprised. It may be good to load client programs first, and only thereafter use undocumented properties; they might be disabled by a client program, even if it runs later.
One of the uses of properties is for communication with procedures evaluating conditional objects: these procedure have the possibility to query all their containing applications for arbitrary property values.
The Name Menu
<SPACE>-D
Name pop-up menu:
Property (design): put a property on the design
Property (instance): put a property on an instance (Application)
Property (object): put a property on an object; this is only possible for objects which are contained in a designs directory
Comment (design): look or put a coment on a design.
Comment (instance): look or put a comment on an instance (Application).
Comment (object): look or put a comment on an object; this is only possible for objects which are contained in a designs directory.
Rename design: rename the design
Instance-name: put an instance name on the selected application
Rename Object: rename selected object in directory
Signal-name: put an signal name on the selected application; this can have side effects if application is not using a rectangle.
Show prop (design): Show the properties of the design.
Show prop (i&o): Show the properties of the selected objects and applications.
Display signal-names: Display signal names of top layer cell.
Signal Names
SignalNames are reserved properties "$SignalName". Their value should be a ROPE.
<Space>-N The names and properties menu
N-Right Display signal names
N-Middle Enter signal name
2.12. Text in ChipnSil
T-middle
Q-middle Draw a text in the current font.
The font selection is made using the control panel. The number of the font in the control panel is used as an index in a fonttable. This font table is set up with the user profile. A change of the userprofile will cause the fonttable to be updated immediately when the userprofile is saved again.
The user profile helps for creation of text. Once a text is in a design, it will not change font on user profile changes.
Q-{Left or Right or CTRL} Edit the selected text.
F-{Left or Right or CTRL} Change the font of the selected text. (Use current selected font with the control panel)
2.13. Conditional objects
See separate documentation. Until now conditional objects can not be design rule checked or put on hierarchical CIF files; However, generating EBES masks or flat CIF files works. There is still danger of committing error 33. Use the <SPACE>-<\> pop up menu.
2.14. Using the Color Display
ChipNDale also uses the color screen as a viewer. It is best to use your user profile to set up the color display. You can also set up the color display interactively. <Space>-B will show the color display pop up menu. Its main entry allows setting up the device, the other entries execute color-model specific commands.
Patterns and Maps
To make reasonable use of the color commands, you have to understand how the colors are generated. Colors are generated in two steps, each of which can be set up separately. Only well matching combinations of these two steps can make reasonable colors.
In a first step a layer causes a certain pattern of pixel values to be or-ed into a bitmap. This pattern may contains several pixels, each of several bits.
In a second step each pixel in the bitmap is mapped through a color map to cause an actual color to appear on the screen.
Generating the pixels can in principle be personalized on a per viewer basis. On normal usage, each technology specifies how its layers are mapped into pixels. The color map however, is part of the display hardware. Only one color map can be active at any time.
There are some separate programs around to influence the color settings
A color tool
A color tool exist (for cmos and nmos only) which allow interactive changing of colors. To get this tool use the color display pop up menu (SPACE-B).
2.15. Useful Things to Know
If output of a design crashes but you want to save it
Look at /indigo/chipndale/temp/......
Did you try SHIFT-SHIFT-SWAT? (hold it down for a couple of seconds).
3. ComandTool commands
Note that capitalization is not significant when giving the commands
3.0 Loading the program
CDNMOS, CDCMOS, CDSil
3.1 Creating new viewers
CDNewNMOS, CDNewCMOS, CDNewSil
Create a new empty design in the appropriate technology.
3.2 Reading in designs
CDRead {optional filename}
Read a ChipNDale design. (.dale file)
The technology of the design on the file must be loaded. If the filename is not specified, chipndale will query for one.
3.3 Color Options
CDColor {optional 4|8} {optional L|R}
If no parameters are on the command lines, a pop up menu is shown.
Cedar: resets the colormap to standard cedar values
Cursor-black: sets the representation of the cursor
Cursor-white: sets the representation of the cursor
4 bit left: 4 bits per pixel on lefthand display
4 bit right: 4 bits per pixel on righthand display
8 bit left: 8 bits per pixel on lefthand display
8 bit right: 8 bits per pixel on righthand display
4. User Profile Options and Commands
It is usually good to specify full path names for filenames mentioned in the user profile; user profile readings are processed with different working directories. The user profile options are shown here with their default values.
WARNING: When ChipNDale is started a reasonable working directory is assumed. When the user profile is edited, NO working directory is assumed.
4.1. Control of the pop-up menu
PopUpMenu.FontFamily: "Helvetica"
PopUpMenu.FontSize: 10
PopUpMenu.FontBold: TRUE
PopUpMenu.FontItalic: FALSE
PopUpMenu.LineHeightChange: 0
4.2. ChipNDale kernel
ChipNDale.NewViewerIconic: FALSE
-- controls creation of viewers showing designs
ChipNDale.ControlViewerOpenIconic: FALSE
-- controls creation of control panel viewers
ColorDisplay.Side: Left
--or Right; this user profile option is shared with the ColorDisplay tool.
ChipNDale.ColorStartBits: -1
-- -1 don't touch color device
-- 0 set up to current bits per pixel mode, if reasonable
-- 4 set up 4 bit per pixel mode
-- 8 set up 8 bit per pixel mode
ChipNDale.RunPrograms: NIL
-- include a list of bcds which should be run whenever
-- ChipNDale is started. (These programs are started before a technology is initialized).
ChipNDale.CatchLowLevelErrors: TRUE
-- DANGEROUS, better don't
-- set to FALSE to help debugging, usually it is possible to continue
ChipNDale.CatchErrorsWhichCauseDeadlock: TRUE
-- DANGEROUS, better don't
-- set carefully FALSE to help debugging, but
-- if errors occur, you loose all your work which is not saved onto files
4.3. NMOS and CMOS-specific user profile options
ChipNDale.NMos.TIP: Default
ChipNDale.CMos.TIP: Default
-- Tip tables can be layered, like for Tioga;
-- Default extends to
-- /indigo/ChipNDale/@/#%/ChipNDale#.TIP /indigo/ChipNDale/@/cd%/ChipNDale.TIP
-- where @ is the Cedar version number, # the ChipNDale technology, % the ChipNDale release number.
4.4. ChipNSil specific user profile options
ChipNDale.ChipNSil.TIP: Default
-- Fonts
ChipNDale.ChipNSil.Font0: "Helvetica10.strike"
ChipNDale.ChipNSil.Font1: "Helvetica7.strike"
ChipNDale.ChipNSil.Font2: "Gates32.strike"
ChipNDale.ChipNSil.Font3: "Template64.strike"
...
ChipNDale.ChipNSil.Font7: "OldEnglish18.strike"
.... ChipNSil supports 8 fonts; which are initialized with the user profile. The user profile designates the font used on creation of the text; once a text is created, its font can NOT be changed with the user profile.
A good place to find fonts is /indigo/altofonts/*.strike or /indigo/Cedar5.2/Top/EssentialFonts.df
Fonts may have a scale, however setting non default scale may cause problems in future; it is not yet decided if that feature will remain. Scale 32 makes a font pixel being lambda square.
ChipNDale.ChipNSil.ScaleFont0: 32
...
ChipNDale.ChipNSil.ScaleFont7: 32
5. The Outside World
5.1. Necessary system
Dorado with Cedar 5.2
5.2. DF files
"©" stands for the current chipndale version number, right now 20 (meaning 0.20) but the zero is seldom written.
"©©" stands for the Cedar release used for the chipndale version, (for ChipNDale 0.20 use 5.2, since ChipNDale 0.20 is programmed in Cedar 5.2.
DF files for designers
/indigo/chipndale/©©/top/cddesign©.df
/indigo/chipndale/©©/top/fooTool©.df where fooTool is the actual tool
It is usually best to create a separate subdirectory for ChipNDale; this allows you to remove it easily when you want to upgrade to a new version. You should run chipndale from the same subdirectory where you store it, so you get the correct default fonts, icons, colortables... (ChipNDale does not use servers as a default because they might be down.)
DF files for programmers
/indigo/chipndale/©©/top/cd©.df
/indigo/chipndale/©©/top/cmos©.df
/indigo/chipndale/©©/top/nmos©.df
DF files for documentation
/indigo/chipndale/©©/top/CDDoc.df
Contains documentations how to use some further tools, how to program extensions to ChipNDale and lots of history.
5.3. Distribution-lists on the Grapevine
ChipndaleImplementors^.pa 
The pure creatures reading your complaints, uh, suggestions; actually we really like to get suggestions.
ChipndaleUsers^.pa 
The user society. You get release messages, status reports and thereon.
ChipndaleDiscussion^.pa 
Open forum for discussion. This list will also get all messages sent to ChipndaleUsers^.pa and some more.
Note: Lists are restricted to Xerox employees, part-time employes and PARC summer students.
6. ChipNDale and Chipmonk
6.1. What's really different from Chipmonk
Some few commands...
All the fuss about technology independency. Its more than you would expect.
Large designs, (32 bit numbers)
Easy to use for clients: All useful commands can also be accessed from calling procedures: Open ended client interfaces.
Its own implementation is based on the client interfaces.
Its list of object types is open ended, including their representation on files.
Multiple viewers per design.
Multiple designs.
Runs on Cedar, gets all the advantages of an integrated environment.
NMOS and CMOS are incompatible, they are implemented as different technologies.
Pop-up menu's.
Terminal viewer for log.
Imports of (References to) other designs
Real repetitions
Conditional objects.
Powerful use of property lists, including saving properties on files.
Checkplots on both color and B&W Versatec plotters.
7. ChipNSil
ChipNSil is really exactly like ChipNDale! You don't have to learn any new command except T-middle to draw texts.
Hint on macro design, to make it easy accessible:
To create macros(=cells) be carefull to make connection points on grid points. Use a grid of 4 for real design, but a grid of 1 while designing a macro. All connection points in a macro should be 1 lambda squares of black which sits on top of a 4 lambda grid point. Make an interestrect to the macro such that the lower left corner sits on a 4 lambda grid point. The size of the interrestrect should then be either a multiple of 4 lambda or a multiple of 4 lambda + 1.