Fork of the excellent esp8266-react - https://github.com/rjwats/esp8266-react
Go to file
2019-06-01 19:27:08 +01:00
data remove roles, as a simplification 2019-05-25 09:45:49 +01:00
interface disable buttons which are not accessable when non-admin user is authenticated 2019-05-31 21:33:12 +01:00
lib initial commit of C++ back end and react front end 2018-02-26 00:11:31 +00:00
media WIP readme 2019-06-01 19:27:08 +01:00
src secure remaining endpoints to authenticated users 2019-05-31 19:58:33 +01:00
.gitignore update platformio.ini to new variables 2018-09-20 09:08:52 +01:00
.travis.yml initial commit of C++ back end and react front end 2018-02-26 00:11:31 +00:00
LICENSE.txt Create LICENSE.txt 2018-03-06 22:49:53 +00:00
platformio.ini Upgrade to material ui 4 2019-05-24 12:19:27 +01:00
README.md WIP readme 2019-06-01 19:27:08 +01:00

ESP8266 React

A simple, extensible framework for IoT projects built on ESP8266/ESP32 platforms with responsive React front-end.

Designed to work with the PlatformIO IDE with limited setup, please read below for build and upload instructions.

Screenshots

Features

Provides many of the features required for IoT projects:

  • Configurable WiFi - Network scanner and WiFi connection screen
  • Configurable Access Point - Can be continuous or automatically enabled when WiFi connection fails
  • Network Time - Synchronization with NTP
  • Remote Firmware Updates - Enable secured OTA updates
  • Security - Protected RESTful endpoints and a secured user interface

The back end is provided by a set of RESTful endpoints and the React based front end is responsive and scales well to various screen sizes.

The front end has the prerequisite manifest file and icon, so it can be added to the home screen of a mobile device if required.

Getting Started

Prerequisites

You will need the following before you can get started.

  • PlatformIO - IDE for development
  • Node.js - For building the interface with npm
  • Bash shell, or Git Bash if you are under windows

Building and uploading the firmware

Pull the project and open it in PlatformIO. PlatformIO should download the ESP8266 platform and the project library dependencies automatically.

The project structure is as follows:

Resource Description
data/ The file system image directory
interface/ React based front end
src/ C++ back end for the ESP8266 device
platformio.ini PlatformIO project configuration file

Building the firmware

Once the platform and libraries are downloaded the back end should be compiling.

WINDOWS BUILDS: If building under Windows you need to delete .piolibdeps/Time/Time.h - due to a file system case insensitivity issue

Uploading the firmware

Standard configuration settings, such as build flags, libraries and device configuration can be found in 'platformio.ini'. The project is configured to upload via serial by default, you can change the upload mechanism to OTA by uncommenting the relevant lines.

See the PlatformIO docs for full details on what you can do with this.

Click the upload button in PlatformIO, or type the upload command if prefer the command line approach:

platformio run -t upload

upload

Building the interface

The interface has been configured with create-react-app and react-app-rewired so the build can customized for the target device. The large artefacts are gzipped and source maps and service worker are excluded from the production build. This reduces the production build to around ~200k, which easily fits on the device.

Change to the 'interface' directory with your bash shell (or Git Bash) and use the standard commands you would with any react app built with create-react-app:

Change to interface directory

cd interface

Download and install the node modules

npm install

Build the interface

npm run build

Note

: The build command will also delete the previously built interface, in the 'data/www' directory, replacing it with the freshly built one ready to upload to the device.

Running the interface locally

You can run a local development server during development to preview changes to the front end them without the need to upload a file system image to the device after each change.

npm start

Note

: To run the interface locally you will need to modify the endpoint root path and enable CORS.

Changing the endpoint root

The endpoint root path can be found in 'interface/.env.development', defined as the environment variable 'REACT_APP_ENDPOINT_ROOT'. This needs to be the root URL of the device running the back end, for example:

REACT_APP_ENDPOINT_ROOT=http://192.168.0.6/rest/

Enabling CORS

You can enable CORS on the back end by uncommenting the -D ENABLE_CORS build flag in 'platformio.ini' then re-building and uploading the firmware to the device. The default settings assume you will be accessing the development server on the default port on http://localhost:3000 this can also be changed if required:

-D ENABLE_CORS
-D CORS_ORIGIN=\"http://localhost:3000\"

Device Configuration

As well as containing the interface, the SPIFFS image (in the 'data' folder) contains a JSON settings file for each of the configurable features. The config files can be found in the 'data/config' directory:

File Description
apSettings.json Access point settings
ntpSettings.json NTP synchronization settings
otaSettings.json OTA update configuration
securitySettings.json Security settings and user credentials
wifiSettings.json WiFi connection settings

The default settings configure the device to bring up an access point on start up which can be used to configure the device:

  • SSID: ESP8266-React
  • Password: esp-react

Building for different devices

This project supports ESP8266 and ESP32 platforms. To support OTA programming, enough free space to upload the new sketch and file system image will be required. It is recommended that a board with at least 2mb of flash is used.

By default, the target device is "esp12e". This is a common ESP8266 variant with 4mb of flash:

ESP12E

The settings file 'platformio.ini' configures the platform and board:

[env:esp12e]
platform = espressif8266
board = esp12e

If you want to build for an ESP32 device, all you need to do is re-configure 'platformio.ini' with your devices settings.

ESP32

Building for the common esp32 "node32s" board for example requires the following configuration:

[env:node32s]
platform = espressif32
board = node32s

Customizing and theming

The framework, and MaterialUI allows for a good degree of custoimzation with little effort.

Theming the app

The app can be easily themed by editing the MaterialUI theme. Edit the theme in 'interface/src/App.js' as you desire:

const theme = createMuiTheme({
  palette: {
    primary: red,
    secondary: deepOrange,
    highlight_idle: blueGrey[900],
    highlight_warn: orange[500],
    highlight_error: red[500],
    highlight_success: green[500],
  },
});

Changing the app icon

You can replace the app icon is located at 'interface/public/app/icon.png' with one of your preference. A 256 x 256 PNG is recommended for best compatibility.

Changing the app name

The app name displayed on the login page and on the menu bar can be modified by editing the REACT_APP_NAME property in 'interface/.env'

REACT_APP_NAME=Funky IoT Project

There is also a manifest file which contains the app name to use when adding the app to a mobile device, so you may wish to also edit 'interface/public/app/manifest.json':

{
  "name":"Funky IoT Project",
  "icons":[
    {
      "src":"/app/icon.png",
      "sizes":"48x48 72x72 96x96 128x128 256x256"
    }
  ],
  "start_url":"/",
  "display":"fullscreen",
  "orientation":"any"
}

Software Overview

Back End

The back end is a set of REST endpoints hosted by a ESPAsyncWebServer instance. The source is split up by feature, for example WiFiScanner.h implements the end points for scanning for available networks.

There is an abstract class SettingsService.h that provides an easy means of adding configurable services/features to the device. It takes care of writing the settings as JSON to SPIFFS. All you need to do is extend the class with your required configuration and implement the functions which serialize the settings to/from JSON. JSON serialization utilizes the excellent ArduinoJson library. Here is a example of a service with username and password settings:

#include <SettingsService.h>

class ExampleSettingsService : public SettingsService {

  public:

    ExampleSettingsService(AsyncWebServer* server, FS* fs)
    : SettingsService(server, fs, "/exampleSettings", "/config/exampleSettings.json") {}

    ~ExampleSettingsService(){}

  protected:

    void readFromJsonObject(JsonObject& root) {
      _username = root["username"] | "";
      _password = root["password"] | "";
    }

    void writeToJsonObject(JsonObject& root) {
      root["username"] = _username;
      root["password"] = _password;
    }

  private:

    String _username;
    String _password;

};

Now this can be constructed, added to the server, and started as such:

ExampleSettingsService exampleSettingsService = ExampleSettingsService(&server, &SPIFFS);

exampleSettingsService.begin();

There will now be a REST service exposed on "/exampleSettings" for reading and writing (GET/POST) the settings. Any modifications will be persisted in SPIFFS, in this case to "/config/exampleSettings.json"

Sometimes you need to perform an action when the settings are updated, you can achieve this by overriding the onConfigUpdated() function which gets called every time the settings are updated. You can also perform an action when the service starts by overriding the begin() function, being sure to call SettingsService::begin():


void begin() {
  // make sure we call super, so the settings get read!
  SettingsService::begin();  
  reconfigureTheService();
}

void onConfigUpdated() {
  reconfigureTheService();
}

void reconfigureTheService() {
  // do whatever is required to react to the new settings
}

Front End

The front end is a bit of a work in progress (as are my react skills), but it has been designed to be a "mobile first" interface and as such should feel very much like an App.

I've tried to keep the use of libraries to a minimum to reduce the artefact size (it's about 150k gzipped ATM).

Future Improvements

  • Reduce boilerplate in interface
  • Provide an emergency config reset feature, via a pin held low for a few seconds
  • Access point should provide captive portal
  • Perhaps have more configuration options for Access point: IP address, Subnet, etc
  • Enable configurable mDNS
  • Introduce authentication to secure the device

Libraries Used