--- layout: developer-doc title: Contributing to Enso category: summary tags: [summary, contributing] order: 2 --- # Contributing to Enso Thank you for your interest in contributing to Enso! We believe that only through community involvement can Enso be the best it can be! There are a whole host of ways to contribute, and every single one is appreciated. The major sections of this document are linked below: - [The Contributor License Agreement](#the-contributor-license-agreement) - [Issues](#issues) - [Feature Enhancements](#feature-enhancements) - [Bug Reports](#bug-reports) - [Hacking on Enso](#hacking-on-enso) - [Design Documentation](#design-documentation) - [System Requirements](#system-requirements) - [Getting the Sources](#getting-the-sources) - [Getting Set Up \(Rust\)](#getting-set-up-rust) - [Getting Set Up \(JVM\)](#getting-set-up-jvm) - [Getting Set Up \(Documentation\)](#getting-set-up-documentation) - [Building Enso](#building-enso) - [Testing Enso](#testing-enso) - [Running Enso](#running-enso) - [Pull Requests](#pull-requests) - [Documentation](#documentation) - [Issue Triage](#issue-triage) - [Out-of-Tree Contributions](#out-of-tree-contributions) - [Helpful Documentation and Links](#helpful-documentation-and-links) All contributions to Enso should be in keeping with our [Code of Conduct](./CODE_OF_CONDUCT.md). ## The Contributor License Agreement As part of your first contribution to this repository, you need to accept the Contributor License Agreement. You will automatically be asked to sign the CLA when you make your first pull request. Any work intentionally submitted for inclusion in Enso shall be licensed under this CLA. The CLA you sign applies to all repositories associated with the Enso project, so you will only have to sign it once at the start of your contributions. ## Issues If you're wanting to get involved with Enso's development and are looking for somewhere to start, you can check out the following tags in our issues: - [Good First Issue](https://github.com/enso-org/enso/labels/Status%3A%20Good%20First%20Issue) - [Help Wanted](https://github.com/enso-org/enso/labels/Status%3A%20Help%20Wanted) You can use the "Size" and "Difficulty" labels that should be assigned to every issue to get a better idea of how much work a given issue might be. ## Feature Enhancements If you feel like you have a suggestion for a change to the way that Enso works as a language, please take a look at the [Enso RFC process](./rfcs/README.md) to learn how to file an RFC for the project. In essence, the RFC process provides a way to propose major changes to the language, the compiler, and the runtime in a way that ensures that they get seen and discussed by all the major stakeholders involved. If, on the other hand, you're asking for a smaller feature, please feel free to submit a [feature request](https://github.com/enso-org/enso/issues/new?assignees=&labels=Type%3A+Enhancement&template=feature-request.md&title=) to the repository. ## Bug Reports While it's never great to find a bug, they are a reality of software and software development! We can't fix or improve on the things that we don't know about, so report as many bugs as you can! If you're not sure whether something is a bug, file it anyway! **If you are concerned that your bug publicly presents a security risk to the users of Enso, please look at our [security guidelines](./SECURITY.md).** Even though GitHub search can be a bit hard to use sometimes, we'd appreciate if you could [search](https://github.com/enso-org/enso/search?q=&type=Issues&utf8=%E2%9C%93) for your issue before filing a bug as it's possible that someone else has already reported the issue. We know the search isn't the best, and it can be hard to know what to search for, so we really don't mind if you do submit a duplicate! Opening an issue is as easy as following [this link](https://github.com/enso-org/enso/issues/new?template=bug-report.md) and filling out the fields. The template is intended to collect all the information we need to best diagnose the issue, so please take the time to fill it out accurately. The reproduction steps are particularly important, as the more easily we can reproduce it, the faster we can fix the bug! It's also helpful to have the output of `enso --version`, as that will let us know if the bug is Operating System or Architecture specific. ### Turning on verbose logs Sometimes, it is helpful to attach a verbose log to your bug report. The way to enable verbose logging depends on which version of Enso you are using. For a standalone distribution (`.exe` on Windows, `.AppImage` on Linux), you can enable verbose logging by passing `-debug.verbose` option. If you are starting the `project-manager`, or language server separately, then pass `--log-level trace` option. With verbose logging, there are a lot of messages printed to the standard output, and it is possible that on slower terminal emulators this will clog the terminal and hence the whole backend. To avoid this, we recommend redirecting the output to `/dev/null`, via a command like `enso -debug.verbose > /dev/null 2>&1`. The logs are kept in a central location `$ENSO_DATA_DIRECTORY/log` - on Linux, they are in `$XDG_DATA_HOME/enso/log` (usually `~/.local/share/enso/log`), and on Windows they are in `%APPDATA%\enso\log`, see [distribution.md](distribution/distribution.md) for details. The log level name consists of the timestamp of the log file creation. There is no automatic log rotation, so you may want to delete the old logs from time to time. ## Hacking on Enso This will get you up and running for Enso development, with only a minimal amount of setup required. Enso's build system is fairly simple, allowing you to bootstrap the compiler as long as you have a minimal set of tools. ### Design Documentation If you're going to start contributing to Enso, it is often a good idea to take a look at the design documentation for the language. These files explain provide both a rigorous specification of Enso's design, but also insight into the _why_ behind the decisions that have been made. These can be found in [`docs/`](README.md), and are organised by the part of the compiler that they relate to. ### System Requirements The following operating systems are supported for developing Enso: - Windows 10 - macOS 10.14 and above - Linux 4.4 and above Currently, we support `x86_64` (all mentioned OS) and `arm64` (Mac only) architectures. You may be able to develop Enso on other systems, but issues arising from unsupported configurations will not be fixed by the core team. In order to build and run Enso you will need the following tools: - [NodeJS](https://nodejs.org/) with the latest LTS version. We recommend installing [a Node version manager that automatically picks up the correct version](https://github.com/shadowspawn/node-version-usage#supporting-products), like [fnm](https://github.com/Schniz/fnm). - [sbt](https://www.scala-sbt.org/) with the same version as specified in [`project/build.properties`](../project/build.properties). - [Maven](https://maven.apache.org/) with version at least 3.6.3. - [GraalVM](https://www.graalvm.org/) with the same version as described in the [`build.sbt`](../build.sbt) file, configured as your default JVM. GraalVM is distributed for different Java versions, so you need a GraalVM distribution for the same Java version as specified in [`build.sbt`](../build.sbt). - [Flatbuffers Compiler](https://google.github.io/flatbuffers) with version 1.12.0. - [Rustup](https://rustup.rs), the rust toolchain management utility. - On MacOS and Linux, the `tar` command is required for running some tests. It should be installed by default on most distributions. - On Windows, the `run` command must be run in the latest version of `Powershell` or in `cmd`. - If you want to be able to build the Launcher Native Image, you will need a native C compiler for your platform as described in the [Native Image Prerequisites](https://www.graalvm.org/reference-manual/native-image/#prerequisites). On Linux that will be `gcc`, on macOS you may need `xcode` and on Windows you need to configure the Developer Command Prompt for Microsoft Visual C++ for the x64 architecture. Managing multiple JVM installations can be a pain, so you can consider using helper tools for that. We recommend: - [Jenv](http://www.jenv.be/) - or [sdkman](https://sdkman.io/) **For users of M1 Mac**: installing GraalVM on M1 Mac requires manual actions, please refer to a [dedicated documentation](./graalvm-m1-mac.md). **For users of MacOS Monterey and later**: building desktop IDE currently requires Python 2 installed in the system. It can be installed using the following commands: ```sh brew install pyenv pyenv install 2.7.18 pyenv global 2.7.18 export PYTHON_PATH=$(pyenv root)/shims/python ``` The flatbuffers `flatc` compiler can be installed from the following locations: - Using the `conda` package manager (`conda install flatbuffers`). This will work on all platforms, but requires some knowledge of `conda` and how its environments work. - Windows users can download binaries directly from the flatbuffers github [releases](https://github.com/google/flatbuffers/releases). - MacOS users can install it via homebrew (`brew install flatbuffers`). ### Getting the Sources Given you've probably been reading this document on GitHub, you might have an inkling where to look!. You can clone Enso using two methods: - **Via HTTPS:** We recommend you only use HTTPS if checking out the sources as read-only. ``` git clone https://github.com/enso-org/enso.git ``` - **Via SSH:** For those who plan on regularly making direct commits, cloning over SSH may provide a better user experience (but requires setting up your SSH Keys with GitHub). ``` git clone git@github.com:enso-org/enso.git ``` ### Getting Set Up (Rust) The Rust code in this repository requires a specific nightly rust toolchain, as defined by [rust-toolchain](../rust-toolchain.toml) override file. The `rustup` will automatically download the appropriate compiler version along with the necessary components. Please consult the [GUI Contribution Guide](../app/gui/docs/CONTRIBUTING.md) to learn details on setting your system up. Quick summary: ```bash enso$ rustup toolchain install stable # Stable toolchain required for the following tools. enso$ cargo +stable install wasm-pack # Install the wasm-pack toolkit. enso$ cargo +stable install cargo-watch # To enable `./run wasm watch` utility ``` The previous three steps shall be enough to build the IDE via `./run wasm build run wasm build --wasm-profile dev`. ### Using Cargo Watch Plus Currently, `cargo-watch` has [many issues](https://github.com/enso-org/cargo-watch-plus), including not working on modern macOS properly. Thus, we've developed a replacement, the [Cargo Watch Plus](https://github.com/enso-org/cargo-watch-plus). To use it, simply export the `USE_CARGO_WATCH_PLUS=1` in your shell and the build system will pick it up instead of the `cargo-watch`. ### Getting Set Up (JVM) In order to properly build the `runtime` component, the JVM running SBT needs to have some dependency JARs available in its module path at startup. To ensure they are available, before running any compilation or other tasks, these dependencies should be prepared. To do so, run the following command in the repository root directory: ```bash sbt bootstrap ``` It is preferred to not run this command from the sbt shell, but in batch mode, because SBT has to be launched again anyway to pick up these JARs at startup. Bootstrap has to be run only when building the project for the first time **and** after each change of Graal version. ### Getting Set Up (Documentation) We enforce automated formatting of all of our documentation and configuration using the fairly common [prettier](https://prettier.io) automatic formatter. You can install prettier for our project by running the following command: ```bash npm install ``` This does, however, mean that you have to have node installed on your system. Please follow the guidelines [above](#getting-set-up-rust) to install node if you have not already done so. The version if prettier is forced by our [`package-lock.json`](../package-lock.json) in order for us to make formatting bumps all at once. You can format all of our documentation and configuration as follows: ```bash npx prettier --write ``` ### Building Enso There are multiple projects in this repository, but all can be built, run and tested using `sbt`. As long as your configuration is correct, with the correct versions of SBT, Rust and GraalVM, the same steps can be followed on all of our supported platforms (Linux, MacOS and Windows). SBT will handle downloading and building library dependencies as needed, meaning that you don't need to handle any of this manually. **Please note** that at the current time, the Windows build of GraalVM is in an experimental state. This means that while it may function, we are not intending to provide work-arounds for building on that platform while it is still in an unstable state. #### Building Enso Components In order to build a specific component (e.g. `runtime`), please follow the following steps. 1. Enter the sbt shell in the repository root directory by typing `sbt`. 2. Change to the project you are concerned with (in our case `runtime`) by executing `project runtime`. 3. Execute `compile` in order to compile the project in question. This will compile the project and all its dependencies as necessary. You can substitute both `bench` and `test` for `compile` in step 3, and the sbt shell will execute the appropriate thing. Furthermore we have `testOnly` and `benchOnly` that accept a glob pattern that delineates some subset of the tests or benchmarks to run (e.g. `testOnly *FunctionArguments*`). #### Building the Interpreter CLI Fat Jar In order to build a fat jar with the CLI component, run the `assembly` task inside the `runner` subproject: ```bash sbt "engine-runner/assembly" ``` This will produce an executable `runner.jar` fat jar and a `runtime.jar` fat jar in the repository root. The `runner.jar` depends only on the `runtime.jar` and a vanilla GraalVM distribution. #### Building the Project Manager Fat Jar In order to build a fat jar with the Project Manager component, run the `assembly` task on the `project-manager` subproject: ```bash sbt "project-manager/assembly" ``` This will produce a `project-manager` fat jar and a `runtime.jar` fat jar in the repository root. #### Building the Launcher Native Binary If you want to build the native launcher binary, you need to ensure that the Native Image component is installed in your GraalVM distribution. To install it, run: ```bash /bin/gu install native-image ``` Then, you can build the launcher using: ```bash sbt launcher/buildNativeImage ``` #### Passing Debug Options GraalVM provides some useful debugging options, including the ability to output the compilation graph during JIT optimisation, and the ASM generated by the JIT. However, as we don't want these things polluting our standard builds, we provide a helper SBT command `withDebug` to allow for passing these options. It supports the following flags: - `--dumpGraphs`: This dumps the IGV (read about [Enso tooling for IGV](../tools/enso4igv/README.md)) graphs for the program to allow for manual analysis and discovery of optimisation failures. - `--showCompilations`: Prints the truffle compilation trace information. - `--printAssembly`: Prints the assembly output from the HotSpot JIT tier. For more information on this sbt command, please see [WithDebugCommand.scala](../project/WithDebugCommand.scala). It is used as an addendum to the basic sbt command you want to run (e.g. `test` from above). The format is `withDebug COMMAND [OPTIONS...]`, and if you need to pass any additional options to `COMMAND` you must do so following a `--`. For example: ``` withDebug run --dumpGraphs --printAssembly -- --run MyFile.enso withDebug benchOnly --showCompilations -- RecursionBenchmark ``` Step by step debugging can be triggered as ``` sbt:runtime> withDebug testOnly --debugger -- *FavoriteTest* ``` One can debug `project-manager` code by executing ``` sbt:project-manager> withDebug run --debugger ``` read more about [debugging Java & Enso code](debugger/README.md). #### Working with Assembly In order to examine the assembly generated by GraalVM and HotSpot you need to provide your JVM install with a dynamic library that supports the dumping of assembly. It can be acquired for MacOS and Linux [here](https://github.com/liuzhengyang/hsdis/), and for windows from [here](http://fcml-lib.com/). There are other methods to acquire it, as well, so please choose one best suited for you. Once you have a copy of the dynamic library, it needs to be placed in `$JVM_HOME/lib/server`. #### Native Image Native image is a capability provided alongside GraalVM that allows the generation of native executables from JVM language programs (such as the Enso interpreter itself). However, it results in significantly degraded peak performance, so it is not part of our roadmap currently. If you would like to experiment with it, you can execute the `buildNativeImage` command in the sbt shell while inside the `runner` project. Please note that while the command is available at the moment, and you are welcome to [report an issue](https://github.com/enso-org/enso/issues/new?assignees=&labels=Type%3A+Bug&template=bug-report.md&title=) with the functionality, any bugs you report will _not_ be considered high priority. **WE CURRENTLY DO NOT SUPPORT THE NATIVE IMAGE BUILD.** #### Using IntelliJ Internally, most of the developers working on the Enso project use IntelliJ as their primary IDE. To that end, what follows is a basic set of instructions for getting the project into a working state in IntelliJ. 1. Clone the project sources. 2. Open IntelliJ 3. File -> New -> Project From Existing Sources. 4. Navigate to the directory into which you cloned the project sources. By default this will be called `enso`. Select the directory, and not the `build.sbt` file it contains. 5. In the 'Import Project' dialogue, select 'Import project from external model' and choose 'sbt'. 6. Where it says 'Download:', ensure you check both 'Library Sources' and 'sbt sources'. 7. In addition, check the boxes next to 'Use sbt shell:' such that it is used both 'for imports' and 'for builds'. 8. Disallow the overriding of the sbt version. 9. Under the 'Project JDK' setting, please ensure that it is set up to use a GraalVM version as described in [System requirements](#system-requirements). You may need to add it using the 'New' button if it isn't already set up. 10. Click 'Finish'. This will prompt you as to whether you want to overwrite the `project` folder. Select 'Yes' to continue. The Enso project will load up with an open SBT shell, which can be interacted with as described above. You will want to use scalafmt for formatting of Scala code, and install Google Java Format for formatting Java code. For more information see the relevant [Style Guides](style-guide/README.md). Depending on the version of GraalVM with which you are working, you may be required to add the following flags to the per-module overrides for IntelliJ's java compiler in order for it to not show spurious errors. This is because some versions of GraalVM export their own closed version of `com.oracle.truffle.api` that IntelliJ picks up preferentially to the version we use for development. You can find these options in `Preferences -> Build, Execution, Deployment -> Compiler -> Java Compiler`. ``` --add-exports org.graalvm.truffle/com.oracle.truffle.api=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.debug=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.dsl=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.exception=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.frame=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.instrumentation=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.interop=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.io=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.library=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.memory=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.nodes=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.object=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.profiles=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.source=ALL-UNNAMED --add-exports org.graalvm.truffle/com.oracle.truffle.api.utilities=ALL-UNNAMED ``` However, as mentioned in the [Troubleshooting](#troubleshooting) section below, the forked nature of execution in the SBT shell means that we can't trivially make use of the IntelliJ debugger. In order to get debugging working, you will need to follow these steps: 1. Go to Run -> Edit Configurations. 2. Click the `+` button in the header of the 'Run/Debug Configurations' dialogue that pops up. 3. Select 'Remote' and name the new configuration appropriately. 4. In the options for that configuration select 'Listen to remote JVM' under 'Debugger mode:' 5. Where it provides the command-line arguments for the remote JVM, copy these and add them to `truffleRunOptions` in [`build.sbt`](build.sbt). Remove the portion of these options after `suspend=y`, including the comma. They are placeholders that we don't use. 6. Alternatively, certain tasks, such as `run`, `benchOnly` and `testOnly` can be used through the `withDebug` SBT command. For this to work, your remote configuration must specify the host of `localhost` and the port `5005`. The command syntax is `withDebug --debugger TASK_NAME -- TASK_PARAMETERS`, e.g. `withDebug --debugger testOnly -- *AtomConstructors*`. 7. Now, when you want to debug something, you can place a breakpoint as usual in IntelliJ, and then execute your remote debugging configuration. Now, in the SBT shell, run a command to execute the code you want to debug (e.g. `testOnly *CurryingTest*`). This will open the standard debugger interface and will allow you to step through your code. **Please be careful** to ensure that you don't commit these changes to the sbt configuration as they are specific to your machine. #### Troubleshooting If you are having issues building Enso, please check the list below before filing an issue with us. - **`StackOverflowError` During Compilation:** Please ensure that your version of sbt is respecting the project's `.jvmopts` settings. We make significant use of recursion when expanding macros for the parser, and these require use of additional stack. Alternatively, you can explicitly pass `-Xss8M` to the `sbt` invocation. - **Debugging Not Working:** The sbt tasks run the invoked programs in a forked JVM. This means that to attach a debugger to it you need to use the JVM remote debugging support. Follow [Enso debugging instructions](debugger/README.md) or see the [Using IntelliJ](#using-intellj) section for instructions. If your problem was not listed above, please [file a bug report](https://github.com/enso-org/enso/issues/new?assignees=&labels=Type%3A+Bug&template=bug-report.md&title=) in our issue tracker and we will get back to you as soon as possible. ### Testing Enso Running the tests for the JVM enso components is as simple as running `sbt / test`. To test the Rust components you can run `./run wasm test`. #### Testing Enso Libraries To test the libraries that are shipped with Enso you need to first build the engine, the easiest way to do so is to run `sbt buildEngineDistribution`. That will create a distribution in the directory `built-distribution`. The engine runner that can be used for running the tests is located at `built-distribution/enso-engine--linux-amd64/enso-/bin/enso` (or `enso.bat` for Windows). To run the tests you can run the following commands (where `enso` refers to the built runner executable as explained above): ```bash enso --run test/Tests # for the Base library enso --run test/Geo_Tests enso --run test/Table_Tests ``` Or to run just a single test (e.g., `Duration_Spec.enso`): ```bash enso --in-project test/Tests --run test/Tests/src/Data/Time/Duration_Spec.enso ``` The Database tests will by default only test the SQLite backend, to test other backends see [`test/Table_Tests/src/Database/README.md`](../test/Table_Tests/src/Database/README.md) for information on how to configure them. The Base tests rely in a few places on the system language. On Linux you can set the `LANG` environment variable to `C` to make sure that the language is configured correctly and run the tests as following: ```bash LANG=C enso --run test/Tests ``` #### Test Dependencies Some test suites require extra setup and enabled only on CI. To replicate the CI environment you should install and run extra services: ```bash # Httpbin go get -v github.com/ahmetb/go-httpbin/cmd/httpbin $(go env GOPATH)/bin/httpbin -host :8080 ``` To run all the stdlib test suites, set `CI=true` environment variable: ```bash env CI=true enso --run test/Tests/ ``` For more details about the CI setup, you can check the `.github/workflows/scala.yml` GitHub workflow. ### Running Enso The language interpreter can be started by the `bin/enso` launcher script located inside of the Enso runtime distribution. Use the following `sbt` command to compile necessary bits (see [Building the Interperter CLI Fat Jar](#building-the-interpreter-cli-fat-jar)) and generate the Enso distribution: ##### Bash ```bash $ sbt buildEngineDistribution $ sbt runEngineDistribution --help ``` Engine package created at built-distribution/enso-engine-0.0.0-dev-linux-amd64/enso-0.0.0-dev - use it or the `sbt runEngineDistribution` command to invoke Enso. ##### PowerShell ```powershell sbt.bat buildEngineDistribution sbt.bat runEngineDistribution --help ``` One can use the `runEngineDistribution` command or execute the launcher: ```bash $ built-distribution/enso-engine-0.0.0-dev-linux-amd64/enso-0.0.0-dev/bin/enso ``` Detailed information on the flags it supports can be shown with the `--help` flag, but the primary functionality is as follows: - `--new PATH`: Creates a new Enso project at the location specified by `PATH`. - `--run PATH`: Executes the interpreter on the Enso source specified by `PATH`. In this case, `PATH` must point to either a standalone Enso file or an Enso project. ##### Bash ```bash distribution/bin/enso --new ~/Hello distribution/bin/enso --run ~/Hello Hello, World! ``` ##### PowerShell ```bash distribution/bin/enso.bat --new ~/Hello distribution/bin/enso.bat --run ~/Hello Hello, World! ``` #### Running IDE You can start [IDE](https://github.com/enso-org/enso/tree/develop/gui) with a development version of the language server. IDE executable has `--external-backend` flag that switches off the bundled backend. That requires you to run the project manager process yourself. Running development version of the IDE is also possible via the `./run` script in the root of the repository: ```bash enso$ ./run gui watch --skip-wasm-opt ``` To build the `project-manager` one needs to launch `sbt` - one way to do it is to execute `./run backend sbt`. When in the _sbt prompt_ one can request compilation of the `project-manager`: ```bash sbt:enso> buildProjectManagerDistribution ``` When the command is completed, a development version of the project manager will have appeared in the `built-distribution` directory. Project manager is there to wait for the IDE to connect to it and then launch the engine with its embedded language server. To build the engine issue following command in the _sbt prompt_: ```bash sbt:enso> buildEngineDistribution ``` Once all the components are assembled, it is time to execute them in orchestration. One can pass following environment variables to `project-manager`: - `ENSO_JVM_OPTS` to for example turn [debugging of the Engine runtime](debugger/README.md) on - `ENSO_JVM_PATH` to force a fixed GraalVM to execute the engine/language server process on - `ENSO_ENGINE_PATH` the path to engine/language server as created by `buildEngineDistribution`, usually `/built-distribution/enso-engine-0.0.0-dev--/enso-0.0.0-dev/` One doesn't need to deal with these options directly, there is an _sbt command_ to orchestrate them all: ```bash sbt:enso> runProjectManagerDistribution ``` The above command invokes `buildProjectManagerDistribution`, `buildEngineDistribution` and then defines `ENSO_ENGINE_PATH` to connect them together and also specifies the `ENSO_JVM_PATH` to the JVM `sbt` process runs on. There also is a simple way to [debug](debugger/README.md). When adding `--debug` option to the _sbt command_: ```bash sbt:enso> runProjectManagerDistribution --debug ``` the system also sets `ENSO_JVM_OPTS=-agentlib:jdwp=transport=dt_socket,address=5005`. Just [configure your Java IDE](debugger/README.md) to listen on port 5005 before invoking the command and you'll be able to debug the engine launched by the project manager. To summarize, these are the steps required to run IDE with the development version of the language server: ```bash enso$ ./run gui watch --skip-wasm-opt ``` together with that also (after launching `./run backend sbt`) following _sbt command_: ```bash sbt:enso> runProjectManagerDistribution ``` #### Language Server Mode The Language Server can be run using the `--server` option. It requires also a content root to be provided (`--root-id` and `--path` options). Command-line interface of the runner prints all server options when you execute it with `--help` option. Below are options uses by the Language Server: - `--server`: Runs the Language Server - `--root-id `: Content root id. - `--path `: Path to the content root. - `--interface `: Interface for processing all incoming connections. Default value is 127.0.0.1 - `--rpc-port `: RPC port for processing all incoming connections. Default value is 8080. - `--data-port `: Data port for visualization protocol. Default value is 8081. To run the Language Server on 127.0.0.1:8080 type: ```bash distribution/bin/enso \ --server \ --root-id 3256d10d-45be-45b1-9ea4-7912ef4226b1 \ --path /tmp/content-root ``` If you want to provide a socket that the server should listen to, you must specify the following options: - `--interface`: The interface on which the socket will exist (e.g. `0.0.0.0`). - `--port`: The port on `interface` where the socket will be opened (e.g. `80`). ## Pull Requests Pull Requests are the primary method for making changes to Enso. GitHub has [fantastic documentation](https://help.github.com/articles/about-pull-requests/) on using the pull request feature. Enso uses the 'fork-and-pull' model of development. It is as described [here](https://help.github.com/articles/about-collaborative-development-models/) and involves people pushing changes to their own fork and creating pull requests to bring those changes into the main Enso repository. Please make all pull requests against the `develop` branch. - We run CI on all contributions to Enso, but it's still useful for you to run the tests yourself locally first! This can be done by running `test` in the `enso` project in sbt. - Additionally, please ensure that your code conforms to the Enso style guides, particularly the [Scala Style Guide](./style-guide/scala.md) and the [Java Style Guide](./style-guide/java.md). Make sure you perform these checks before _every_ pull request. You can even add [git hooks](https://git-scm.com/book/en/v2/Customizing-Git-Git-Hooks) before every push to make sure that you can't forget. - Every pull request to the Enso repository is reviewed by a member of the core team! You'll get assigned a reviewer based on the areas your PR touches, but please feel free to ask for a specific person if you've worked with them in a specific area before! - If you have questions, or would like to begin the review process before your PR is 'done', please use the [Draft Pull Requests](https://github.blog/2019-02-14-introducing-draft-pull-requests/) feature on GitHub. Doing so will allow you to make use of our CI infrastructure as part of your development process. Once the reviewer approves your pull request it will be tested by our continuous integration provider before being merged. If we request changes to your PR, please feel free to discuss the suggestions and comments! We can only achieve the best results through open collaboration. ## Documentation Documentation improvements are very welcome! For now, the main documentation available is the _developer_ documentation for the language, which can be found at the [dev docs site](https://enso.org/docs/developer). The source for this documentation is found in the [`docs/`](.) folder, and can be altered from there. Documentation pull requests will be reviewed in exactly the same way as normal pull requests. To find documentation-related issues, sort by the [Category: Documentation](hhttps://github.com/enso-org/enso/labels/Category%3A%20Documentation) label. ## Issue Triage Sometimes issues can be left open long after the bug has been fixed. Other times, a bug might go stale because something has changed in the meantime. It can be helpful to go through older bug reports and make sure that they are still valid. Load up an older issue, double check that it's still true, and leave a comment letting us know if it is or is not. The [least recently updated](https://github.com/enso-org/enso/issues?q=is%3Aissue+is%3Aopen+sort%3Aupdated-asc) sort is good for finding issues like this. Contributors with sufficient permissions can help by adding labels to help with issue triage. If you're looking for somewhere to start, take a look at the [Difficulty: Beginner](https://github.com/enso-org/enso/labels/Difficulty%3A%20Beginner) issue label, as well as the [Status: Help Wanted](https://github.com/enso-org/enso/labels/Status%3A%20Help%20Wanted) and [Status: Good First Issue](https://github.com/enso-org/enso/labels/Status%3A%20Good%20First%20Issue) labels. ## Out-of-Tree Contributions As helpful as contributing to Enso directly is, it can also be just as helpful to contribute in other ways outside this repository: - Answer questions in the [Discord](https://chat.luna-lang.org) or on [StackOverflow](https://stackoverflow.com/questions/tagged/enso). ## Helpful Documentation and Links For people new to Enso, and just starting to contribute, or even for more seasoned developers, some useful places to look for information are: - The [design documentation](./README.md). - The community! Don't be afraid to ask questions.