Clean Movies Browser

CleanMovieBrowser is a sample project that showcases how to download movies information from a public repo TMDB.

The goal of the project is to combine popular libraries/tools and demonstrate best development practices by utilizing up to date tech-stack and presenting modern Android application Architecture that is modular, scalable, maintainable, and testable. This application could be useful for providing a base for larger scalable real world projects.

Project characteristics and tech-stack

This project takes advantage of best practices, many popular libraries and tools in the Android ecosystem. Most of the libraries are in the stable version unless there is a good reason to use non-stable dependency.

• Tech-stack
  • 100% Kotlin + Coroutines - perform background operations
  • Retrofit - HTTP client
  • OkHttp - networking
  • Jetpack
    • Navigation - in-app navigation
    • LiveData - data objects that notify views when the underlying database changes.
    • Flow - flow is a type that can emit multiple values sequentially
    • Lifecycle - perform an action when lifecycle state changes
    • ViewModel - store and manage UI-related data in a lifecycle conscious way
    • Room - SQLite object mapping library
  • Koin - dependency injection
  • Glide - image loading library
  • Stetho - application debugging
  • Timber - a logger with a small, extensible API which provides utility on top of Android's normal Log class
• Modern Architecture
  • Clean Architecture (at feature module level)
  • Single activity architecture using Navigation component
  • MVVM + MVI (presentation layer)
  • Dynamic feature modules
  • Android Architecture components (ViewModel, LiveData, Navigation)
  • Android KTX - Jetpack Kotlin extensions
• Testing
  • Unit Tests (JUnit 5 via android-junit5)
  • UT Tests (Espresso)
  • Mockk - mocking framework
  • Kluent - assertion framework
• UI
  • Material design
  • Reactive UI
• Gradle
  • Gradle Kotlin DSL
  • Plugins (SafeArgs, android-junit5)
  • Dependency locks
  • Versions catalog\

Architecture

Clean architecture has been followed. Feature related code is placed inside one of the feature modules. We can think about each feature as the reusable component, equivalent of microservice or private library.

The modularized code-base approach provides few benefits:

• better separation of concerns. Each module has a clear API., Feature related classes live in different modules and can't be referenced without explicit module dependency.
• features can be developed in parallel eg. by different teams
• each feature can be developed in isolation, independently from other features
• faster compile time

Module types and module dependencies

This diagram presents dependencies between project modules (Gradle sub-projects).

Note that due usage of Android dynamic-feature module dependencies are reversed (feature modules are depending on app module, not another way around).

We have three kinds of modules in the application:

• app module - this is the main module. It contains code that wires multiple modules together (dependency injection setup, NavHostActivity, etc.) and fundamental application configuration (retrofit configuration, required permissions setup, custom application class, etc.).
• application-specific x_library modules that some of the features could depend on. This is helpful if you want to share some assets or code only between few feature modules.
• feature modules - the most common type of module containing all code related to a given feature.

Feature module structure

Clean architecture is the "core architecture" of the application, so each feature module contains own set of Clean architecture layers:

Notice that app module and library_x modules structure differs a bit from feature module structure.

Each feature module contains non-layer components and 3 layers with distinct set of responsibilities.

Presentation layer

This layer is closest to what the user sees on the screen. The presentation layer is a mix of MVVM (Jetpack ViewModel used to preserve data across activity restart) and MVI (actions modify the common state of the view and then new state is edited to a view via LiveData to be rendered).

common state (for each view) approach derives from Unidirectional Data Flow and Redux principles.

Components:

• View (Fragment) - presents data on the screen and pass user interactions to View Model. Views are hard to test, so they should be as simple as possible.
• ViewModel - dispatches (through LiveData) state changes to the view and deals with user interactions (these view models are not simply POJO classes).
• ViewState - common state for a single view
• NavManager - singleton that facilitates handling all navigation events inside NavHostActivity (instead of separately, inside each view)

Domain layer

This is the core layer of the application. Notice that the domain layer is independent of any other layers. This allows to make domain models and business logic independent from other layers. In other words, changes in other layers will have no effect on domain layer eg. changing database (data layer) or screen UI (presentation layer) ideally will not result in any code change withing domain layer.

Components:

• UseCase - contains business logic
• DomainModel - defies the core structure of the data that will be used within the application. This is the source of truth for application data.
• Repository interface - required to keep the domain layer independent from the data layer (Dependency inversion).

Data layer

Manages application data and exposes these data sources as repositories to the domain layer. Typical responsibilities of this layer would be to retrieve data from the internet and optionally cache this data locally.

Components:

• Repository is exposing data to the domain layer. Depending on application structure and quality of the external APIs repository can also merge, filter, and transform the data. The intention of these operations is to create high-quality data source for the domain layer, not to perform any business logic (domain layer use case responsibility).

• Mapper - maps data model to domain model (to keep domain layer independent from the data layer).

• RetrofitService - defines a set of API endpoints.

• DataModel - defines the structure of the data retrieved from the network and contains annotations, so Retrofit (Moshi) understands how to parse this network data (XML, JSON, Binary...) this data into objects.

Dependency management

This project utilizes multiple mechanics to easily share the same versions of dependencies.

App library dependencies

External dependencies (libraries) are defined using versions catalog feature in the settings.gradle file. These dynamic library versions are locked using Gradle locking dependency mechanism - concrete dependency versions are stored in MODULE_NAME/gradle.lockfile files.

To update lock files run ./gradlew test lint s --write-locks command and commit updated gradle.lockfile files to repository.

Each feature module depends on the app module, so dependencies are shared without need to add them explicitly in each feature module.

Gradle plugin dependencies

Gradle plugins are defined in pluginManagement block (settings.gradle file).

Dynamic versions aren't supported for Gradle plugins, so locking dependency mechanism can't be used (like for app library dependencies), and thus versions of some libraries & plugins have to be hardcoded in the gradle.properties file.

There is no easy way to share id between pluginManagement block and buildSrc folder, so plugin ids (also used within build scripts), have to be duplicated in the GradlePluginId file.

Shared dependencies

Gradle is missing proper built-in mechanism to share dependency versions between app library dependency and Gradle plugin dependency eg. Navigation component library uses Safe Args Gradle plugin with the same version.

To enable sharing all versions that are used for both plugins and libraries are defined in gradle.properties.

Unfortunately this technique cannot be applied to older Gradle plugins (added by classpath, not by pluginManagement), so some version in the gradle.properties are still duplicated.

Design decisions

Read related articles to have a better understanding of underlying design decisions and various trade-offs.

• Multiple ways of defining Clean Architecture layers
• More coming soon

Getting started

There are a few ways to open this project.

Android Studio

1. Android Studio -> File -> New -> From Version control -> Git
2. Enter https://github.com/roymithun/CleanMovieBrowser.git into URL field an press Clone button

Command-line + Android Studio

1. Run git clone https://github.com/roymithun/CleanMovieBrowser.git command to clone project
2. Open Android Studio and select File | Open... from the menu. Select cloned directory and press Open button

Known issues

• False positive "Unused symbol" for a custom Android application class referenced in AndroidManifest.xml file (Issue 27971)
• False positive "Function can be private" (Issue KT-33610)
• False positive cannot access class (Issue 16077). This is fixed in InteliJ IDEA 2021.1 EAP 1 afair.
• Gradle has no way to share dependency versions between library and Gradle plugin or prod and test version of the library (Issue 16077)
• JUnit 5 does not support tests with suspended modifier (Issue 1914)
• Gradle dependencies can't be easily shared between app libraries and Gradle plugins gradle/gradle#16077