element-x-android/docs/_developer_onboarding.md

# Developer on boarding

<!--- TOC -->

* [Introduction](#introduction)
  * [Quick introduction to Matrix](#quick-introduction-to-matrix)
    * [Matrix data](#matrix-data)
      * [Room](#room)
      * [Event](#event)
    * [Sync](#sync)
  * [Rust SDK](#rust-sdk)
    * [Matrix Rust Component Kotlin](#matrix-rust-component-kotlin)
    * [Build the SDK locally](#build-the-sdk-locally)
  * [The Android project](#the-android-project)
  * [Application](#application)
    * [Jetpack Compose](#jetpack-compose)
    * [Global architecture](#global-architecture)
    * [Template and naming](#template-and-naming)
  * [Push](#push)
  * [Dependencies management](#dependencies-management)
  * [Test](#test)
  * [Code coverage](#code-coverage)
  * [Other points](#other-points)
    * [Logging](#logging)
    * [Translations](#translations)
    * [Rageshake](#rageshake)
  * [Tips](#tips)
* [Happy coding!](#happy-coding)

<!--- END -->

## Introduction

This doc is a quick introduction about the project and its architecture.

It's aim is to help new developers to understand the overall project and where to start developing.

Other useful documentation:

- all the docs in this folder!
- the [contributing doc](../CONTRIBUTING.md), that you should also read carefully.

### Quick introduction to Matrix

Matrix website: [matrix.org](https://matrix.org), [discover page](https://matrix.org/discover).
*Note*: Matrix.org is also hosting a homeserver ([.well-known file](https://matrix.org/.well-known/matrix/client)).
The reference homeserver (this is how Matrix servers are called) implementation is [Synapse](https://github.com/matrix-org/synapse/). But other implementations
exist. The Matrix specification is here to ensure that any Matrix client, such as Element Android and its SDK can talk to any Matrix server.

Have a quick look to the client-server API documentation: [Client-server documentation](https://spec.matrix.org/v1.3/client-server-api/). Other network API
exist, the list is here: (https://spec.matrix.org/latest/)

Matrix is an open source protocol. Change are possible and are tracked using [this GitHub repository](https://github.com/matrix-org/matrix-doc/). Changes to the
protocol are called MSC: Matrix Spec Change. These are PullRequest to this project.

Matrix object are Json data. Unstable prefixes must be used for Json keys when the MSC is not merged (i.e. accepted).

#### Matrix data

There are many object and data in the Matrix worlds. Let's focus on the most important and used, `Room` and `Event`

##### Room

`Room` is a place which contains ordered `Event`s. They are identified with their `room_id`. Nearly all the data are stored in rooms, and shared using
homeserver to all the Room Member.

*Note*: Spaces are also Rooms with a different `type`.

##### Event

`Events` are items of a Room, where data is embedded.

There are 2 types of Room Event:

- Regular Events: contain useful content for the user (message, image, etc.), but are not necessarily displayed as this in the timeline (reaction, message
  edition, call signaling).
- State Events: contain the state of the Room (name, topic, etc.). They have a non null value for the key `state_key`.

Also all the Room Member details are in State Events: one State Event per member. In this case, the `state_key` is the matrixId (= userId).

Important Fields of an Event:

- `event_id`: unique across the Matrix universe;
- `room_id`: the room the Event belongs to;
- `type`: describe what the Event contain, especially in the `content` section, and how the SDK should handle this Event;
- `content`: dynamic Event data; depends on the `type`.

So we have a triple `event_id`, `type`, `state_key` which uniquely defines an Event.

#### Sync

This is managed by the Rust SDK.

### Rust SDK

The Rust SDK is hosted here: https://github.com/matrix-org/matrix-rust-sdk.

This repository contains an implementation of a Matrix client-server library written in Rust.

With some bindings we can embed this sdk inside other environments, like Swift or Kotlin, with the help of [Uniffi](https://github.com/mozilla/uniffi-rs).
From these kotlin bindings we can generate native libs (.so files) and kotlin classes/interfaces.

#### Matrix Rust Component Kotlin

To use these bindings in an android project, we need to wrap this up into an android library (as the form of an .aar file).  
This is the goal of https://github.com/matrix-org/matrix-rust-components-kotlin. 
This repository is used for distributing kotlin releases of the Matrix Rust SDK.
It'll provide the corresponding aar and also publish them on maven.

Most of the time you want to use the releases made on maven with gradle:

```groovy
implementation("org.matrix.rustcomponents:sdk-android:latest-version")
```

You can also have access to the aars through the [release](https://github.com/matrix-org/matrix-rust-components-kotlin/releases) page.

#### Build the SDK locally

If you need to locally build the sdk-android you can use
the [build](https://github.com/matrix-org/matrix-rust-components-kotlin/blob/main/scripts/build.sh) script.

For this, you first need to ensure to setup :

- rust environment (check https://rust-lang.github.io/rustup/ if needed)
- cargo-ndk < 2.12.0
```shell
cargo install cargo-ndk --version 2.11.0
```
- android targets
```shell
rustup target add aarch64-linux-android armv7-linux-androideabi x86_64-linux-android i686-linux-android
```
- checkout both [matrix-rust-sdk](https://github.com/matrix-org/matrix-rust-sdk) and [matrix-rust-components-kotlin](https://github.com/matrix-org/matrix-rust-components-kotlin) repositories
```shell
git clone git@github.com:matrix-org/matrix-rust-sdk.git
git clone git@github.com:matrix-org/matrix-rust-components-kotlin.git
```

Then you can launch the build script from the matrix-rust-components-kotlin repository with the following params:

- `-p` Local path to the rust-sdk repository
- `-o` Optional output path with the expected name of the aar file. By default the aar will be located in the corresponding build/outputs/aar directory.
- `-r` Flag to build in release mode
- `-m` Option to select the gradle module to build. Default is sdk.
- `-t` Option to to select an android target to build against. Default will build for all targets.

So for example to build the sdk against aarch64-linux-android target and copy the generated aar to ElementX project:

```shell
./scripts/build.sh -p [YOUR MATRIX RUST SDK PATH] -t aarch64-linux-android -o [YOUR element-x-android PATH]/libraries/rustsdk/matrix-rust-sdk.aar
```

Finally let the `matrix/impl` module use this aar by changing the dependencies from `libs.matrix.sdk` to `projects.libraries.rustsdk`:

```groovy
dependencies {
    api(projects.libraries.rustsdk)    // <- use the local version of the sdk. Uncomment this line.
    //implementation(libs.matrix.sdk)  // <- use the released version. Comment this line.
}
```

You are good to test your local rust development now!

### The Android project

The project should compile out of the box.

This Android project is a multi modules project.

- `app` module is the Android application module. Other modules are libraries;
- `features` modules contain some UI and can be seen as screen or flow of screens of the application;
- `libraries` modules contain classes that can be useful for other modules to work.

A few details about some modules:

- `libraries-core` module contains utility classes;
- `libraries-designsystem` module contains Composables which can be used across the app (theme, etc.);
- `libraries-elementresources` module contains resource from Element Android (mainly strings);
- `libraries-matrix` module contains wrappers around the Matrix Rust SDK.

Most of the time a feature module should not know anything about other feature module.
The navigation glue is currently done in the `app` module.

Here is the current simplified module dependency graph:

<!-- Note: a full graph can be generated using `./tools/docs/generateModuleGraph.sh`. -->
<!-- Note: doc can be found at https://mermaid.js.org/syntax/flowchart.html#graph -->
```mermaid
flowchart TD
    subgraph Application
    app([:app])--implementation-->appnav([:appnav])
    end
    subgraph Features
    featureapi([:features:*:api])
    featureimpl([:features:*:impl])
    end
    subgraph Libraries
        subgraph Matrix
        matrixapi([:matrix:api])
        matriximpl([:matrix:impl])
        end
    libraryarch([:libraries:architecture])
    libraryapi([:libraries:*:api])
    libraryimpl([:libraries:*:impl])
    end
    subgraph Matrix RustSdk
    RustSdk([Rust Sdk])
    end

    app--implementation-->featureimpl
    app--implementation-->libraryimpl
    appnav--implementation-->featureapi
    appnav--implementation-->libraryarch
    featureimpl--api-->featureapi
    featureimpl--implementation-->matrixapi
    featureimpl--implementation-->libraryapi
    featureimpl--implementation-->libraryarch
    matriximpl--implementation-->matrixapi
    matrixapi--api-->RustSdk
    matriximpl--api-->RustSdk
    featureapi--implementation-->libraryarch
    libraryimpl--api-->libraryapi
```

### Application

This Android project mainly handle the application layer of the whole software. The communication with the Matrix server, as well as the local storage, the
cryptography (encryption and decryption of Event, key management, etc.) is managed by the Rust SDK.

The application is responsible to store the session credentials though.

#### Jetpack Compose

Compose is essentially two libraries : Compose Compiler and Compose UI. The compiler (and his runtime) is actually not specific to UI at all and offer powerful
state management APIs. See https://jakewharton.com/a-jetpack-compose-by-any-other-name/

Some useful links:

- https://developer.android.com/jetpack/compose/mental-model
- https://developer.android.com/jetpack/compose/libraries
- https://developer.android.com/jetpack/compose/modifiers-list
- https://android.googlesource.com/platform/frameworks/support/+/androidx-main/compose/docs/compose-api-guidelines.md#api-guidelines-for-jetpack-compose

About Preview

- https://alexzh.com/jetpack-compose-preview/

#### Global architecture

Main libraries and frameworks used in this application:

- Navigation state with [Appyx](https://bumble-tech.github.io/appyx/). Please
  watch [this video](https://www.droidcon.com/2022/11/15/model-driven-navigation-with-appyx-from-zero-to-hero/) to learn more about Appyx!
- DI: [Dagger](https://dagger.dev/) and [Anvil](https://github.com/square/anvil). Please
  watch [this video](https://www.droidcon.com/2022/06/28/dagger-anvil-learning-to-love-dependency-injection/) to learn more about Anvil!
- Reactive State management with Compose runtime and [Molecule](https://github.com/cashapp/molecule)

Some patterns are inspired by [Circuit](https://slackhq.github.io/circuit/)

Here are the main points:

1. `Presenter` and `View` does not communicate with each other directly, but through `State` and `Event`
2. Views are compose first
3. Presenters are also compose first, and have a single `present(): State` method. It's using the power of compose-runtime/compiler.
4. The point of connection between a `View` and a `Presenter` is a `Node`.
5. A `Node` is also responsible for managing Dagger components if any.
6. A `ParentNode` has some children `Node` and only know about them.
7. This is a single activity full compose application. The `MainActivity` is responsible for holding and configuring the `RootNode`.
8. There is no more needs for Android Architecture Component ViewModel as configuration change should be handled by Composable if needed.

#### Template and naming

This documentation provides you with the steps to install and use the AS plugin for generating modules in your project. 
The plugin and templates will help you quickly create new features with a standardized structure.

A. Installation

Follow these steps to install and configure the plugin and templates:

1. Install the AS plugin for generating modules :
   [Generate Module from Template](https://plugins.jetbrains.com/plugin/13586-generate-module-from-template)
2. Import file templates in AS :
   - Navigate to File/Manage IDE Settings/Import Settings
   - Pick the `tools/templates/file_templates.zip` files
   - Click on OK
3. Configure generate-module-from-template plugin : 
   - Navigate to AS/Settings/Tools/Module Template Settings
   - Click on + / Import From File
   - Pick the `tools/templates/FeatureModule.json`

Everything should be ready to use.

B. Usage

Example for a new feature called RoomDetails:

1. Right-click on the features package and click on Create Module from Template
2. Fill the 2 text fields like so:
    - MODULE_NAME = roomdetails
    - FEATURE_NAME = RoomDetails
3. Click on Next
4. Verify that the structure looks ok and click on Finish
5. The modules api/impl should be created under `features/roomdetails` directory.
6. Sync project with Gradle so the modules are recognized (no need to add them to settings.gradle).
7. You can now add more Presentation classes (Events, State, StateProvider, View, Presenter) in the impl module with the `Template Presentation Classes`.
   To use it, just right click on the package where you want to generate classes, and click on `Template Presentation Classes`. 
   Fill the text field with the base name of the classes, ie `RootRoomDetails` in the `root` package.
   

Note that naming of files and classes is important, since those names are used to set up code coverage rules. For instance, presenters MUST have a
suffix `Presenter`,states MUST have a suffix `State`, etc. Also we want to have a common naming along all the modules.

### Push

**Note** Firebase Push is not yet implemented on the project.

Please see the dedicated [documentation](notifications.md) for more details.

This is the classical scenario:

- App receives a Push. Note: Push is ignored if app is in foreground;
- App asks the SDK to load Event data (fastlane mode). We have a change to get the data faster and display the notification faster;
- App asks the SDK to perform a sync request.

### Dependencies management

We are using [Gradle version catalog](https://docs.gradle.org/current/userguide/platforms.html#sub:central-declaration-of-dependencies) on this project.

All the dependencies (including android artifact, gradle plugin, etc.) should be declared in [../gradle/libs.versions.toml](libs.versions.toml) file.
Some dependency, mainly because they are not shared can be declared in `build.gradle.kts` files.

[Renovate](https://github.com/apps/renovate) is set up on the project. This tool will automatically create Pull Request to upgrade our dependencies one by one. A [dependency dashboard issue](https://github.com/vector-im/element-x-android/issues/150) is maintained by the tool and allow to perform some actions.

### Test

We have 3 tests frameworks in place, and this should be sufficient to guarantee a good code coverage and limit regressions hopefully:

- Maestro to test the global usage of the application. See the related [documentation](../.maestro/README.md).
- Combination of [Showkase](https://github.com/airbnb/Showkase) and [Paparazzi](https://github.com/cashapp/paparazzi), to test UI pixel perfect. To add test,
  just add `@Preview` for the composable you are adding. See the related [documentation](screenshot_testing.md) and see in the template the
  file [TemplateView.kt](../features/template/src/main/kotlin/io/element/android/features/template/TemplateView.kt). We create PreviewProvider to provide
  different states. See for instance the
  file [TemplateStateProvider.kt](../features/template/src/main/kotlin/io/element/android/features/template/TemplateStateProvider.kt)
    - Tests on presenter with [Molecule](https://github.com/cashapp/molecule) and [Turbine](https://github.com/cashapp/turbine). See in the template the
      class [TemplatePresenterTests](../features/template/src/test/kotlin/io/element/android/features/template/TemplatePresenterTests.kt).

**Note** For now we want to avoid using class mocking (with library such as *mockk*), because this should be not necessary. We prefer to create Fake
implementation of our interfaces. Mocking can be used to mock Android framework classes though, such as `Bitmap` for instance.

### Code coverage

[kover](https://github.com/Kotlin/kotlinx-kover) is used to compute code coverage. Only have unit tests can produce code coverage result. Running Maestro does
not participate to the code coverage results.

Kover configuration is defined in the main [build.gradle.kts](../build.gradle.kts) file.

To compute the code coverage, run:

```bash
./gradlew koverMergedReport
```

and open the Html report: [../build/reports/kover/merged/html/index.html](../build/reports/kover/merged/html/index.html)

To ensure that the code coverage threshold are OK, you can run

```bash
./gradlew koverMergedVerify
```

Note that the CI performs this check on every pull requests.

Also, if the rule `Global minimum code coverage.` is in error because code coverage is `> maxValue`, `minValue` and `maxValue` can be updated for this rule in
the file [build.gradle.kts](../build.gradle.kts) (you will see further instructions there).

### Other points

#### Logging

**Important warning: ** NEVER log private user data, or use the flag `LOG_PRIVATE_DATA`. Be very careful when logging `data class`, all the content will be
output!

[Timber](https://github.com/JakeWharton/timber) is used to log data to logcat. We do not use directly the `Log` class. If possible please use a tag, as per

````kotlin
Timber.tag(loggerTag.value).d("my log")
````

because automatic tag (= class name) will not be available on the release version.

Also generally it is recommended to provide the `Throwable` to the Timber log functions.

Last point, note that `Timber.v` function may have no effect on some devices. Prefer using `Timber.d` and up.


#### Translations

Translations are handled through localazy. See [the dedicated README.md file](../tools/localazy/README.md) for information on how
to configure new modules etc.

#### Rageshake

Rageshake is a feature to send bug report directly from the application. Just shake your phone and you will be prompted to send a bug report.

Bug reports can contain:

- a screenshot of the current application state
- the application logs from up to 15 application starts
- the logcat logs

The data will be sent to an internal server, which is not publicly accessible. A GitHub issue will also be created to a private GitHub repository.

Rageshake can be very useful to get logs from a release version of the application.

### Tips

- Element Android has a `developer mode` in the `Settings/Advanced settings`. Other useful options are available here; (TODO Not supported yet!)
- Show hidden Events can also help to debug feature. When developer mode is enabled, it is possible to view the source (= the Json content) of any Events; (TODO
  Not supported yet!)
- Type `/devtools` in a Room composer to access a developer menu. There are some other entry points. Developer mode has to be enabled; (TODO Not supported yet!)
- Hidden debug menu: when developer mode is enabled and on debug build, there are some extra screens that can be accessible using the green wheel. In those
  screens, it will be possible to toggle some feature flags; (TODO Not supported yet!)
- Using logcat, filtering with `Compositions` can help you to understand what screen are currently displayed on your device. Searching for string displayed on
  the screen can also help to find the running code in the codebase.
- When this is possible, prefer using `sealed interface` instead of `sealed class`;
- When writing temporary code, using the string "DO NOT COMMIT" in a comment can help to avoid committing things by mistake. If committed and pushed, the CI
  will detect this String and will warn the user about it. (TODO Not supported yet!)

## Happy coding!

The team is here to support you, feel free to ask anything to other developers.

Also please feel free to update this documentation, if incomplete/wrong/obsolete/etc.

**Thanks!**