Issie (Interactive Schematic Simulator with Integrated Editor) is an application for digital circuit design and simulation. It is targeted at students and hobbyists that want to get a grasp of Digital Electronics concepts in a simple and fun way. Issie is designed to be beginner-friendly and guide the users toward their goals via clear error messages and visual clues. Issie is developed and actively used in teaching at Imperial College London.
- If you are just interested in using the application, jump to the Getting Started section.
- If you want user documentation and news go to the web pages.
- If you are interested in a more detailed description of Issie please check out the Wiki.
For more technical info about the project, read on. This documentation is partly based on the excellent VisUAL2 documentation, given the similarity in the technology stack used.
For the Issie website go here.
The application is mostly written in F#, which gets transpiled to JavaScript via the Fable compiler. Electron is then used to convert the developed web-app to a cross-platform application. Electron provides access to platform-level APIs (such as access to the file system) which would not be available to vanilla browser web-apps.
Webpack 5 is the module bundler responsible for the JavaScript concatenation and automated building process: the electron-webpack build is automated using the pre-existing scripts under the scripts directory.
The drawing capabilities are provided (now) by a custom schemetic editor library implemented in F# and specialised for digital components.
The choice of F# as main programming language for the app has been dictated by a few factors:
- The success of the VisUAL2, which uses a similar technology stack;
- Strongly typed functional code tends to be easy to maintain and test, as the type-checker massively helps you;
- Imperial College EEE/EIE students learn such language in the 3rd year High-Level-Programming course, hence can maintain the app in the future;
- F# can be used with the powerful Elmish framework to develop User Interfaces in a Functional Reactive Programming fashion.
If you just want to run the app go to the releases page and download and run the latest prebuilt binary for your platform (Windows or Macos). Issie will require in total about 200M of disk space.
- Windows: unzip *.zip anywhere and double-click the top-level
Issie.exe
application in the unzipped files.- If you get a security warning saying something like: Microsoft Defender SmartScreen prevented an unrecognized app from starting. Running this app might put your PC at risk.
More info then:
- Click More Info
- Then click Run Anyway
- If you get a security warning saying something like: Microsoft Defender SmartScreen prevented an unrecognized app from starting. Running this app might put your PC at risk.
More info then:
- Macos: Double click the dmg file and run the application inside the folder, or drag and drop this to install.
- The binaries are not signed. You will need to perform a one-off security bypass. Alternatively (and this may be simpler to do), you can do this by running:
sudo xattr -rd com.apple.quarantine /Applications/issie.app
Issie installs and runs without making system changes - all of its code is inside the directory you download.
You can delete this and replace it by a later version of Issie. Each design sheet is stored in a similarly named file under the project directory.
The subdirectory backup
there contains a large numbers of backup snapshots for design recovery.
These are not needed for Issie operation so you can delete them - or even the whole backup
directory, if you wish.
Issie binaries will not run (in some cases) from a networked file location (found on many cluster machines).
If you have this problem navigate to the top-level directory containing the Issie binaries in a command window
and type issie.exe --no-sandbox
. See tomcl#125 for details.
Once you open up Issie and are ready to go, feel free to open one of the Demo Projects from the start-up window. These are there to show you what a complete Issie project looks like and enable you to have fun with it without having to design and build it from scratch. Every time you reopen a demo project it will be reset to its initial state.
If you want to get started as a developer, follow these steps.
Download and install (if you already have these tools installed just check the version constraints).
- .Net 7 SDK.
- Node.js v16. v16 LTS - NOT latest 18
- Node.js includes the
npm
package manager, so this does not need to be installed separately. - If you are using a different version of Node for developmnet on other projects, global install (the default) may interfere with this. You will need to do a more complex local node install.
- Node.js includes the
- (recommended) Visual Studio 2022 which includes F# 7.0, Install with:
- Workload: .Net Desktop development
- Ticked: F# language support
- (recommended) install hyper.js (ideal) or Windows Terminal for Windows.
-
Download & unzip the Issie repo, or clone it locally, or fork it on github and then clone it locally.
-
Install
Node.js
by running the installer. It might be necessary to reboot your computer after the various dependencies, such as Chocolatey, are installed. -
Navigate to the project root directory from the master-before-new-simulation branch (which contains this README) in a command-line interpreter, or start one from directory context menu.
-
Run
build.cmd
under Windows orbuild.sh
under linux or macos. This will download and install all dependencies then launch the application in dev mode with HMR. -
Once Issie has loaded, stop the master-before-new-simulation Issie with
Ctrl+C
and switch to the master branch and runnpm install
.
- HMR: the application will automatically recompile and update while running if you save updated source files
- To initialise and reload:
File -> reload page
- To exit: after you exit the application the auto-compile script will terminate after about 15s
- To recompile the whole application again run
npm run dev
. Runnpm run debug
for the debug mode (this is going to be a lot slower than dev). - To generate distributable binaries for dev host system
npm run dist
. - If you have changed
packet.json
and therefore need to remake the lock filepaket-lock.json
usenpm install
. - On windows
build killzombies
will terminate orphan node and dotnet processes which occasionally happen using this build chain after unusual terminations
NB - in parallel with the above compilation, Issie code will always compile without errors (but not run)under dotnet. Compilation should be identical but when unsure why there is an error it is very helpful to build the current code under VS or VSC and get easier to find error messages. Similarly, VS or VSC can be used with confidence to refactor code, testing with compilation. Building under VS or VSC cannot work because the code depends on electron and Node APIs to work.
package-lock.json
contains exact package versions and is downloaded from the repo. Normally you don't need to change this. The standard build above will runnpm ci
which checks and audits packages but does not change the lock file.- If you need to add upgrade a package (in
package.json1
) usenpm install
to recreate a lock file, which can be pushed to the repo. - Single packages can conveniently be changed or added using
npm upgrade name
ornpm [-D] install name
instead of editingpackage.json
. - If a package audits with a problem use
npm ls name
to find which of the required packages use it (usually upgrading or replacing them will remove the problem).
A clean build will work equally well on macos, however things are more likely to go wrong if you have previously installed conflicting packages:
-
Legacy versions of
dotnet
- can if needed be removed as here:curl -O https://raw.githubusercontent.com/dotnet/sdk/main/scripts/obtain/uninstall/dotnet-uninstall-pkgs.sh chmod u+x dotnet-uninstall-pkgs.sh sudo ./dotnet-uninstall-pkgs.sh
-
Root permissions in dev files. For dev to work smoothly you need every configuration file to be installed under your own username, so you have r/w access. This will break if you ever find yourself using
sudo
to root install software, or if you have done this some time in the past. In that case you can temporarily get round issues by usingsudo
to run the development (or the generated app) with admin privileges. This is the wrong thing to do. Instead you should usechown -R `whoami` dir
for each directory that might have the files with bad permissions. Typically your dev directory.
and/usr/local
.
-
Uninstalling and reinstalling latest dotnet is helpful if dotnet has been installed wrong.
-
For Apple silicon Mac users, you should use the Arm64 version of .NET in order to get the best results. You can get it from the official Microsoft Website, using their installer. It is likely you will need to specify the location of the .NET installation to Visual Studio. This is under Visual Studion > Preferences > SDK Locations > .NET Core.
Although the dev chain is complex, it is now very smooth and identical for all platforms. Each of these steps can be performed as needed:
- You need
Dotnet SDK
andNode
installed. Dotnet SDK gives you F#. dotnet tool restore
gets you the dev tools:Fable
compiler,Fake
build automation,paket
dotnet package manager. (Node package management is vianpm
which comes with Node).dotnet paket install
installs all of the dotnet-side packages needednpm ci
downloads and audits correct versions of all of the npm packages.npm install
will redo the versions if these have changed and generate an updated lock file.npm run dev
,npm run dist
, npm rundevfast
: scripts defined inpackage.json
which control developmment (with HMR) or production compilation with Fable, and packing using Webpack 5.- The
build.cmd
andbuild.sh
scripts package the above steps adding some not usually necessary directory cleaning - you can run them individually in order if you have problems.
- To update the tool versions (not normally needed) edit
dotnet-tools.json
. - To change the dotnet packages used (advanced) change
paket.dependencies
at top level andpaket.references
in the directory of the relevant.fsproj
file. Currently dotnet packages are not pinned to versions so latest compatible versions are always used. This is probably wrong but seems to work well. - To interface to a new Node package from F# see the excellent Fable documentation. The best way to do this is to write an F# interface file which provides
static typing (like a typescript definition file). In fact there is a wonderful automatic converter ts2fable which generates F# interfaces from typescript
.d
files. This works well, but manual adjutsment is needed for anything complex. See the Electon API interface in Issie which was generated in this way from a published electron API.d
files - in that case the manual adjustment was quite unpleasant because Electron API is very complex. - To understand Elmish and MVU read the excellent Elmish book
- For more documentation on Issie in addition to XML code comments see the Issie Wiki
Electron bundles Chromium (View) and node.js (Engine), therefore as in every node.js project, the package.json
file specifies the (Node) module dependencies.
- dependencies: node libraries that the executable code (and development code) needs
- dev-dependencies: node libraries only needed by development tools
Additionally, the section "scripts"
:
"scripts": {
"clean-dev-mac": "sudo killall -9 node && sudo killall -9 dotnet && sudo killall -9 issie",
"clean-dev-win": "taskkill /f /im node.exe && taskkill /f /im dotnet.exe && taskkill /f /im issie.exe",
"compile": "dotnet fable src/Main -s && dotnet fable src/Renderer -s",
"dev": "dotnet fable watch src/Main -s --run npm run devrenderer",
"devrenderer": "dotnet fable watch src/Renderer -s --define ASSERTS --run npm run start",
"start": "cross-env NODE_ENV=development node scripts/start.js",
"build": "cross-env NODE_ENV=production node scripts/build.js",
"pack": "npm run compile && npm run build && electron-builder --dir",
"dist": "npm run compile && npm run build && electron-builder",
"buildonly": "electron-builder",
"compile-sass": "cd src/renderer/scss && node-sass main.scss main.css"
}
Defines the in-project shortcut commands as a set of <key> : <value
lines, so that when we use npm run <stript_key>
it is equivalent to calling <script_value>
.
For example, in the root of the project, running in the terminal npm run dev
is equivalent to the command line:
dotnet fable watch src/Main -s --run npm run devrenderer
This runs fable 3 to transpile the main process, then (--run
is an option of fable to run another command) runs script devrenderer
to transpile to javascript and watch the F# files in the renderer process. After the renderer transpilation is finished
start.js script will be run. This invokes webpack
to pack and lauch the javascript code, under electron, and also watches for changes in the javascript code, and hot loads these on the running application
As result of this, at any time saving an edited F# renderer project file causes (nearly) immediate:
- fable transpile to from F# to javascript file (dependent F# files may also be transpiled)
- webpack hot load of any changed javascript files to the running electron application
The build system depends on a Fake
file build.fsx
. Fake is a DSL written in F# that is specialised to automate build tasks. Build.fsx has targets representing build tasks, and normally these are run via build.cmd
or build.sh
, instead of using dotnet fake
directly:
build <target>
==>dotnet fake build -t <target>
The source code consists of two distinct sections transpiled separately to Javascript to make a complete Electron application.
- The electron main process runs the Electron parent process under the desktop native OS, it starts the app process and provides desktop access services to it.
- The electron client (app) process runs under Chromium in a simulated browser environment (isolated from the native OS).
Electron thus allows code written for a browser (HTML + CSS + JavaScript) to be run as a desktop app with the additional capability of desktop filesystem access via communication between the two processes.
Both processes run Javascript under Node.
The src/Main/Main.fs
source configures electron start-up and is boilerplate. It is transpiled to the root project directory so it can be automatically picked up by Electron.
The remaining app code (in )
The code that turns the F# project source into renderer.js
is the FABLE compiler followed by the Node Webpack bundler that combines multiple Javascript files into a single renderer.js
.
The compile process is controlled by the .fsproj
files (defining the F# source) and webpack.additions.main.js
, webpack.additions.renderer.js
which define how Webpack combines F# outputs for both electron main and electron app processes and where the executable code is put.
This is boilerplate which you do not need to change; normally the F# project files are all that needs to be modified.
Subfolder or file | Description |
---|---|
Main/main.fs |
Code for the main electron process that sets everything up - not normally changed |
Renderer/Common/* |
Provides some common types and utilities, as well as interfaces to libraries APIs and custom libraries |
Renderer/Interface/* |
Contains low-level interface functions, and all the low-level file management |
Renderer/DrawBlock/* |
Contains all the SVG-based schematic editor code in F# |
Renderer/Simulator/* |
Contains the logic to analyse and simulate a schematic sheet |
Renderer/UI/* |
Contains the UI logic |
./renderer.fs |
Top-level file that drives the renderer code: contains Elmish MVU loop and Electron menu code |
Currently tests are very old, and will not work. They are based on F# Expecto testing library and in principle the widthinferrer and simulator code (which runs under dotnet) could be tested here.
Contains static files used in the application.
Contains source information that controls the project documentation web site https://tomcl.github.io/issie/.
Issie allows the users to create projects and files within those projects. A Issie project is simply a folder named <project-name>
that contains an empty file named <project_name>.dprj
(dprj stands for diagram project). The project folder any non-zero number of design files, each named <component_name>.dgm
(dgm stands for diagram). each deisgn file represents one design sheet of a hierarchical hardware design, sheets can contain, as components, other sheets.
When opening a project, Issie will initially search the given repository for .dgm
files, parse and load their content, and allow the user to open them in Issie or use them as components in other designs.
To reinstall the build environment (without changing project code) rerun build.cmd
(Windows) or build.sh
(Linux and MacOS).
npm run dist
will generate the correct binaries for your system under /dist
.