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Notes WASM GO

An experiment project ( part of an InternShip ) to see how far we can push WASM with GO to use it as a note taking app integrated with git and encryption logic in wasm to store notes in a secure way to a GitHub repo.

Deploy with Vercel

Runing locally

Running this locally without crazy scripts requires 3 terminals

  • Terminal 1: for building wasm file
  • Terminal 2: for running the frontend server
  • Terminal 3: for running the backend proxy server ( to avoid CORS issues )

Terminal 1

requires go >1.16

Backend has a script to build the wasm file and copy it to the frontend folder

cd backend
bash build.sh

Terminal 2

requires node >14

Add configuration

Create a .env file in the frontend folder and add the following

  • VITE_APP_CLIENT_ID : GitHub OAuth App Client ID
  • VITE_APP_CLIENT_SECRET : GitHub OAuth App Client Secret
  • VITE_APP_ENCRYPT_SECRET: Encryption secret ( used to encrypt notes before sending them to GitHub )

in frontend/src/repo.json add json object with the following

key value
Repo GitHub repo name in format: USER/REPO
Branch GitHub repo branch name
owner GitHub repo owner name
cors_proxy_url CORS proxy url ( to avoid CORS issues )

now the final file should look like this

{
  "Repo": "USER/REPO",
  "Branch": "main",
  "owner": "USER",
  "cors_proxy_url": "http://...."
}

Run the server

cd frontend
npm i -g pnpm
pnpm i
pnpm run dev

This will start up the frontend server on a specific port (usually 5173). navigate to your address localhost:5173

Terminal 3

requires go >1.16

cd proxy
go run main.go

Docs

frontend

saving note

graph LR;
	fe(markdown note)-->wasm(get encrypted text for note)-->wasm2(write to file)-->i(push file to remote)
Loading

fetching note

graph LR;
	fe(encrypted note)-->wasm(decrypt to target string)-->fe2(display to editor)
Loading

Wasm

The main package provides functionality for a Go program intended to be executed as a WebAssembly module (WASM). It includes features for interacting with the file system, performing Git operations, and encrypting/decrypting text. This technical documentation describes the various components and functions within the main package.

Imports

The main package imports the following packages:

Package Description
errors Provides functions for manipulating errors.
path/filepath Implements utility functions to manipulate file paths.
strings Implements utility functions for manipulating strings.
syscall/js Enables interaction between Go code and JavaScript in the browser.
time Provides functionality for measuring and displaying time.
crypto/aes Implements the Advanced Encryption Standard (AES) symmetric-key encryption algorithm.
crypto/cipher Provides interfaces for symmetric encryption and decryption.
encoding/hex Provides functions for encoding and decoding hexadecimal strings.
github.com/go-git/go-billy/v5 Implements an abstraction for file systems.
github.com/go-git/go-billy/v5/memfs Implements an in-memory file system.
github.com/go-git/go-git/v5 Implements Git operations in Go.
github.com/go-git/go-git/v5/plumbing/cache Implements an object cache for Git operations.
github.com/go-git/go-git/v5/plumbing/object Implements object-related functionality for Git operations.
github.com/go-git/go-git/v5/plumbing/transport/http Provides HTTP transport support for Git operations.
github.com/go-git/go-git/v5/storage/filesystem Implements a file system storage backend for Git operations.

Variables

repoLocation (string): Specifies the location of the Git repository. Filesystem (memfs.Filesystem): Represents an in-memory file system. Struct

Functions

  • regiterCallbacks(): Registers go functions ( type of js.Func ) to be called from javascript

Exposed functions

All exposed function return a javascript function to prevent deadlocks nested javascript function returns a Promise object for:

  1. Asynchronous execution: WebAssembly is designed to execute code asynchronously, which means that it can perform long-running operations without blocking the main thread. By returning a Promise object, the caller can wait for the operation to complete without blocking the main thread.

  2. Error handling: Promises provide a standardized way to handle errors in asynchronous code. By returning a Promise object, the caller can use the catch method to handle any errors that occur during the operation.

  3. Interoperability: Promises are a standard feature of JavaScript, which means that they can be used by any JavaScript code that interacts with the WebAssembly module. This makes it easier to integrate WebAssembly code with existing JavaScript code.

  4. Chaining: Promises can be chained together using the then method, which allows for more complex asynchronous workflows. By returning a Promise object, the caller can chain multiple operations together to create more complex workflows.

git_clone

await git_clone(url: string)

used to clone a github reposity to memory

Parameter Description
url url address for GitHub repo

git_push

await git_push(
	url: string,
	accessTocken: string,
	username: string,
	email: string,
	file: string,
	commitMessage: string
)

commits file path given in paramter and pushes to remote url

Parameter Description
url url address for GitHub repo
accessTocken Access tocken with scope repo
username username for adding author to commit
email email for adding author to commit
file file path to commit
commitMessage to add commit message

encrypt_text

await encrypt_text(
	text: string,
	key : string
)

returns an AES encrypted text encoded in hexadecimal for better redabilty

Parameters Description
text text string to encrypt
key A string ( size of 16 or 24 or 32 bit ) which is used as key for encryption

decrypt_text

await decrypt_text(
	text: string,
	key: string
)

return a decrypted string

Parameters Description
text hexadecimal encoded AES encrypted text
key A string ( size of 16 or 24 or 32 bit ) which is used as key for decryption

createfile

await create_file(
	file: string
)

create an empty file inside in-memory file system

Parameters Description
file file path to create file

touchNcat

await touchNcat(
	file: string,
	content: string
)

creates a file to filepath with contents

Parameters Description
file file path to create file
content content to add in file

Usage in go

To use the main package, import it into your Go program and execute the main() function. Ensure that the necessary dependencies are properly installed.

Note: This package is specifically designed to be used as a WebAssembly module and interacts with JavaScript in the browser.

Here is an example usage of the main package:

package main

import (
	"fmt"
	"syscall/js"
)

// Example function that calls the Go functions from JavaScript
func exampleUsage() {
	// Call the createFile function
	createFile := js.Global().Get("createFile")
	result := createFile.Invoke("file.txt")
	if result.Type() == js.TypeObject && result.Get("constructor").Get("name").String() == "Promise" {
		// Handle the promise asynchronously
		promise := result
		promise.Call("then", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// File created successfully
			fmt.Println("File created:", args[0].String())
			return nil
		})).Call("catch", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Error occurred while creating the file
			err := args[0]
			fmt.Println("Error creating file:", err.Get("message").String())
			return nil
		}))
	}

	// Call the ls function
	ls := js.Global().Get("ls")
	result = ls.Invoke("directory")
	if result.Type() == js.TypeObject && result.Get("constructor").Get("name").String() == "Promise" {
		// Handle the promise asynchronously
		promise := result
		promise.Call("then", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Files listed successfully
			filesArray := args[0]
			for i := 0; i < filesArray.Length(); i++ {
				fmt.Println("File:", filesArray.Index(i).String())
			}
			return nil
		})).Call("catch", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Error occurred while listing files
			err := args[0]
			fmt.Println("Error listing files:", err.Get("message").String())
			return nil
		}))
	}

	// Call the git_clone function
	gitClone := js.Global().Get("git_clone")
	result = gitClone.Invoke("https://github.com/user/repo.git")
	if result.Type() == js.TypeObject && result.Get("constructor").Get("name").String() == "Promise" {
		// Handle the promise asynchronously
		promise := result
		promise.Call("then", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Repository cloned successfully
			fmt.Println("Repository cloned:", args[0].String())
			return nil
		})).Call("catch", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Error occurred while cloning the repository
			err := args[0]
			fmt.Println("Error cloning repository:", err.Get("message").String())
			return nil
		}))
	}

	// Call the git_push function
	gitPush := js.Global().Get("git_push")
	result = gitPush.Invoke("https://github.com/user/repo.git", "accessToken", "username", "email", "file.txt", "Commit message")
	if result.Type() == js.TypeObject && result.Get("constructor").Get("name").String() == "Promise" {
		// Handle the promise asynchronously
		promise := result
		promise.Call("then", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Push successful
			fmt.Println("Pushed to repository")
			return nil
		})).Call("catch", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Error occurred while pushing to the repository
			err := args[0]
			fmt.Println("Error pushing to repository:", err.Get("message").String())
			return nil
		}))
	}

	// Call the encrypt_text function
	encryptText := js.Global().Get("encrypt_text")
	result = encryptText.Invoke("plain text", "encryptionKey")
	if result.Type() == js.TypeObject && result.Get("constructor").Get("name").String() == "Promise" {
		// Handle the promise asynchronously
		promise := result
		promise.Call("then", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Text encrypted successfully
			encryptedText := args[0].String()
			fmt.Println("Encrypted text:", encryptedText)
			return nil
		})).Call("catch", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Error occurred while encrypting the text
			err := args[0]
			fmt.Println("Error encrypting text:", err.Get("message").String())
			return nil
		}))
	}

	// Call the decrypt_text function
	decryptText := js.Global().Get("decrypt_text")
	result = decryptText.Invoke("encrypted text", "encryptionKey")
	if result.Type() == js.TypeObject && result.Get("constructor").Get("name").String() == "Promise" {
		// Handle the promise asynchronously
		promise := result
		promise.Call("then", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Text decrypted successfully
			decryptedText := args[0].String()
			fmt.Println("Decrypted text:", decryptedText)
			return nil
		})).Call("catch", js.FuncOf(func(this js.Value, args []js.Value) interface{} {
			// Error occurred while decrypting the text
			err := args[0]
			fmt.Println("Error decrypting text:", err.Get("message").String())
			return nil
		}))
	})
}

func main() {
	// Register Go functions to be called from JavaScript
	registerCallbacks()

	// Example usage
	exampleUsage()

	// Block indefinitely
	select {}
}

In the above example, we import the necessary packages and define an example function exampleUsage() that demonstrates calling the Go functions from JavaScript. The exampleUsage() function showcases the usage of functions such as createFile(), ls(), git_clone(), git_push(), encrypt_text(), and decrypt_text().

The main() function registers the Go functions as callbacks to be called from JavaScript and then calls the exampleUsage() function. Finally, the program blocks indefinitely using the select {} statement to keep the WebAssembly module running.

This example demonstrates the basic usage of the main package for a Go program intended to be executed as a WebAssembly module.