Skip to content
This repository has been archived by the owner on Feb 1, 2024. It is now read-only.
/ ink-playground Public archive

Browser Based Playground for editing, sharing & compiling ink! Smart Contracts

License

Notifications You must be signed in to change notification settings

use-ink/ink-playground

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

ink! Playground

⚠️ This project has been archived. It is no longer maintained.

ink! Playground

An ink! Playground which provides a Browser based IDE for editing Smart Contracts written in ink!. A live deployment of the App can be found under ink-playground.substrate.io.

Features:

  • Uses the Monaco editor
  • Implements a WebAssembly version of Rust Analyzer for code editing
  • Allows saving and sharing of Smart Contract code
  • Implements a one click compile functionality of ink! Smart Contracts to WASM which is provided by a backend service

Table of Contents

Getting started

On Mac-OS

Before proceeding you need to configure the following environment variables (either on your terminal or better persist them into your .zshrc file):

export PATH="/usr/local/opt/llvm/bin/:$PATH"
export CC=/usr/local/opt/llvm/bin/clang
export AR=/usr/local/opt/llvm/bin/llvm-ar

On every OS

The ink! playground is a fronted app which is developed using TypeScript and React. It is contained in the packages/playground folder.

The repo contains a Rust backend which is implemented with the actix-web framework and which can be found in the 'crates/backend' folder.

The backend serves the frontend app and it also provides the backend services for compilation and Github gists creation(which we use to provide the code sharing functionality).

To clone and build the whole project on your local computer, enter:

  1. git clone https://github.com/paritytech/ink-playground

  2. cd ink-playground

  3. make install

  4. make generate

  5. make build

Then pull and tag the docker images which are used by the backend to compile, test & format Smart Contracts:

  1. make docker-pull-images

Finally, start the backend with:

  1. make backend-run

The last command starts the Rust webserver locally on your computer. You can then access localhost:4000 from your browser to open the locally compiled ink! Playground open.

Detailed usage instructions:

The make file and ink! playground

Important commands from the make file:

  • make install
    Installs all the required TypeScript dependencies from all monorepo packages by using yarn install.
  • make generate
    There are parts of the Frontend which are generated by some rust crates. Namely, these are:
    • rust analyzer
      The WebAssembly version of Rust Analyzer which is run by Frontend through some Web Workers. Generating only the rust analyzer WASM file can be done with make generate-rust-analyzer.
    • change.json
      A serialized version of the CrateGraph and project source dependencies of an ink! Smart Contract. This file is provided to the WASM version of rust analyzer and is generated under /packages/_generated/change. Generating only the change.json file can be done with make generate change-json.
    • bindings
      The actix-web Webserver backend provides some endpoints to the Frontend (/compile, /test, /gist). The crate generate-bindings from the Rust Monorepo automatically creates TypeScript types for the communication with these endpoints and provides them in /packages/_generated/commontypes. Generating only the bindings can be done with make generate bindings.
  • make build
    Builds the complete ink! Playground, involves:
    • frontend the react Frontend which needs to be provided with all three ingredients which are generated by make generate, as well as all npm dependencies which are installed by make install. Can also be build independently by make playground-build.
    • backend the actix-web backend which serves the Frontend and provides endpoint for testing, compilation and sharing of Smart Contract code. Can also be build independently by make backend-build.
  • make backend-run
    Starts a the actix web server backend and serves the release version of the playground frontend from the folder packages/playground/dist. Make sure to run make build first to build all the required Rust and frontend dependencies.
  • make playground-start
    Starts a dev build of the frontend repo of ink! Playground which allows for easy debugging of the Frontend code / UI, involving Rust Analyzer. Note that the compile/gist functionalities will not be available when invoking make playground-start
  • make docker-build
    Then deployment of the ink! Playground app is done in our CI by building and uploading the docker image which we generate from our Dockerfile. Running make docker-build generates this docker image and tags it with ink-playground.
  • make docker-run
    Starts the Docker container of playground under the sysbox runtime. Make sure that you have the sysbox docker runtime installed on your computer. Instructions on how to install it can be found here.
  • make ci
    With make ci, we run the majority of tests which we execute in our Github CI.

crate-extractor

Overview of the (sub-)repos

We can divide this Repo into two main contributions:

  • The folder crates is a monorepo containing the Rust source code, its separate crates serve functionalities like the web server which serves the frontend app, the backend services for Smart Contract compilation and Github Gist generation (code sharing) or the rust analyzer functionalities for the IDE.
  • The folder packages is a TypeScript/React monorepo, containing the Frontend App which is served by the Rust backend.

The contributions of crates

  • backend

    This is the main crate of the web server which serves the frontend app. It is based on the Actix Web framework. It serves the directory of the compiled playground app which is located in the /packages/playground/dist folder after executing make build (which involves the compilation of the production bundle of the Frontend app).

  • change_json

    The IDE of the frontend app contains a WebAssembly version of Rust Analyzer. We need to provide Rust Analyzer the source code and crate graph of the analyzed smart contract. Usually, Rust Analyzer will scan the file system, load the dependency data of a rust project into an object, the change object and will send this object to its db. Since we can not access the file system in browser based wasm, we had to find another approach. For this we (de-)serialize the change object which is encoding the data. This crate contains the methods/traits to (de-)serialize the change object.

  • contract

    This is the sample crate which serves as a blueprint for creating the serialized change object.

  • crate_extractor

    Parses Crates and CrateGraph (the package dependency graph) of a Rust Project into a JSON file for Rust Analyzer(=RA) and provides a library for (de-)serialization of these data structures which can be referenced by a WASM implementation of RA.

    For a detailed description, refer to the corresponding section of ARCHITECTURE.md

    Usage:

    Enter:

    gh clone https://github.com/paritytech/ink-playground

    cd ink-playground

    cargo run -p crate-extractor -- create -i <input> -o <output>

    Where <input> points to the Cargo.toml of the project you which to analyze and <output> denotes the path to the resulting '.json' file. Both are optional parameters and default to /Cargo.toml and ./change.json.

  • generate_bindings

    Utilizes ts-rs to auto-generate TypeScript bindings for the API endpoints that the Actix Web framework of the backend crate provides. The bindings are generated into the /packages/_generated/commontypes folder, where they are consumed by the Frontend App.

  • rust_analyzer_wasm

    A LSP (Language Server Protocol) of Rust Analyzer for the monaco editor which is compiled to WebAssembly and which we execute in the Browser. This crate gets compiled to the /packages/playground/pkg subfolder of the playground package. Its compiled version provides the executable WebAssembly code and the corresponding TypeScript types.

  • sandbox

    Provides the sandbox environment which triggers the compilation of ink! Smart Contracts which is executed by the backend server from the backend crate.

The contributions of packages

  • playground

This is the main Frontend Webapp which provides the ink! Playground with Rust Analyzer and compilation functionalities.

  • ink-editor

This isolates the components providing the monaco editor with integrated Rust Analyzer and the API endpoints for code compilation and Github gist creation into its own package.

  • components

Contains the basic UI building blocks. Makes use of PRIMEREACT UI library.

  • _generated

This is the target directory for auto generated types, files & bindings. It currently contains the change package which receives the change.json file from the crate_extractor crate and the commontypes package which carries the bindings and types which allow the Frontend (specifically the API being contained in ink-editor package) to communicate with the backend service for code compilation and Gist generation.

  • docker_tests

Based on the jest testing framework, this packages executes some basic tests against an already running playground container (serves website, provides compile endpoint).

The Dockerfiles for ink! playground

We have two Dockerfiles for two different docker images in this repo: ink-playground and ink-compiler:

  • ink-compiler
    Is used to compile ink! Smart Contracts in a sandboxed environment. We execute the resulting image in a sandboxed environment without network access. The image is a derived from docker.io/paritytech/ink-ci-linux:production and ships with a pre-compiled ink! Smart Contract.

  • ink-playground
    Is the main ink! Playground Dockerfile which is generated by the ./Dockerfile. It is used to deploy the playground on our server. It is executed by using Nestybox's Sysbox runtime. We require this runtime to compile ink! Smart Contracts through a sandboxed Docker in Docker execution within the executed Docker image by using the ink-compiler Docker image.

    The Image is build in multiple steps by a multi stage build process to improve its image size.

    For a better understanding of the steps which are involved in building this image, refer to the build dependencies section of ARCHITECTURE.md.