\documentclass{projdoc} \input{meta.tex} \title{Research document} \begin{document} \tablestables \newpage \section{Introduction} \section{Game engine} \subsection{Introduction} To build a game engine, it must first be understood how it operates. The functionalities it requires and how these functionalities work together must be determined. In this section, the general functioning of a game engine and the different parts required are described. \subsection{Findings} A game engine is not the game itself but a platform with which games are built. It should provide the functionalities with which the game is constructed. The purpose of a game engine is not to create data out of nothing. Instead, data is read, and the correlating features and effects are generated. However, the engine is also used to create these files, referred to as ``assets.'' The game engine must be able to accept a certain format of these assets---whether levels, sprites, or textures---and convert them into usable data. \subsubsection{Layers} A game engine is composed of multiple layers, each with its own functions. These layers are divided into the following categories:\noparbreak \begin{description} \item[Resource manager] Responsible for what happens when the engine is launched, including loading data formats. \item[Application] Manages the run loop, time, code execution, and events (e.g.~input events). \item[Window/\glspl{hid}] Handles input and events. \item[Renderer] Responsible for drawing the necessary objects on the screen, usually once per frame. \item[Debugging support] Provides testing for the engine, such as logging or performance profiling. \item[Scripting layer] Runs scripts, such as Lua or Python. \item[Memory systems] Handles and monitors memory usage. \item[Physics] Adds specific physics to objects. \item[Audio] Processes audio. \item[AI] Provides artificial inteligent behavior. \end{description} \subsubsection{Structures} The above mentioned layers should be structured, somehow. One of the requirements is that the game engine's API uses a so-called gameObject (with one or more component(s)). The gameObject is described in more detail at \cref{sec:Gameobjects/components}. There are multiple structures that could be used to structure a game engine. It's of course possible to use inheritance. A major disadvantages of inheritance is that it's not flexible. However, the provided class diagram of the game engine's API already specifies that composition should be used (in stead of inheritance). So, let's take a look at structures that use composition. The Decorator design pattern (as shown in \cref{fig:decorator}) could be used to structure the game engine. A gameObject's propperties/behavior is determined by one (or more) components. The Decorator design pattern allows to modify an object's propperties/behavior by adding one (or more) Decorators. The object that is modified, could be the gameObject and the components could be the Decorators. This is not exactly the same as the required API, but it's very close. A major disadvantage of such Decorator design pattern, is that the interface of all components should be the same (they should share the same methods), because the client (which is the scene in our case) can only call/reach the components through the interface. This would require very general methods (at the interface), which might make the programming harder \autocite{man:DecoratorDesignPattern,man:Decorator}. \begin{figure} \centering \includepumldiag{img/decorator-design-pattern.puml} \caption{Decorator design pattern} Source: \autocite{img:Decorator} \label{fig:decorator} \end{figure} TODO: Add Extension Objects design pattern (if this is applicable)! Another (very popular) design pattern to structure the game engine, is the Entity Component System (\gls{ecs}). The \gls{ecs} is made out of three main subsystems, namely entities, components and systems. Entities are just IDs. An entity is made out of a gameObject and one (or more) components. Components are the classes that hold the data. The components determine what kind of entity it is (e.g. a sprite, audio, and so on). Systems take care of the behavior of the entities. Systems mainly read and write the enity's components data. The \gls{ecs} clearly distinguishes the data (components) from the functionality (systems). % TODO: Continue this explanation (also add some diagrams to make the ECS more clear)! There are many C/C++ libraries available, completely dedicated to \gls{ecs}. The most popular libraries are shown in \cref{tab:popularECSLibraries}. The popularity is based on the amount of stars on GitHub. \begin{table} \centering \begin{tabular}{ll@{\qquad}lr} \toprule \textbf{Name} & \textbf{Short Description} & \textbf{Stars} & \textbf{License}\\ \midrule EnTT & Fast and reliable entity-component system & 10k & MIT\\ Flecs & A Multithreaded Entity Component System & 6.3k & MIT\\ EntityX & Fast, type-safe C++ entity component system & 2.2k & MIT\\ \bottomrule \end{tabular} \caption{Popular \gls{ecs} libraries} Source: \autocite{github:awesome-ecs} \label{tab:popularECSLibraries} \end{table} It is, of course, not necessary to use a library to implement an \gls{ecs} architecture. However, it seems very hard to achieve the same performance as a library \autocite{github:ecsfaq}. \subsection{Conclusion} \section{Third-party Tools} \subsection{Introduction} Developing a game engine from scratch requires a significant amount of time, as many different features are necessary. Fortunately, some of these features have already been developed and can be reused in the form of frameworks and third-party tools/libraries. The decision to use third-party libraries, and the selection of which ones to use, directly influences the development process of the game engine. In this section, several third-party frameworks and tools available for use are described. \subsection{Findings} \subsubsection{Media Frameworks} A game engine must have the ability to handle user input, render graphics, and process audio. Several large frameworks are available that provide these features and are already widely used by other game engines. The two most popular and best-supported options are \gls{sdl2} and \gls{sfml}. \paragraph{SDL2} % TODO: ref?sdl2 According to its official website, \gls{sdl2} is \emph{``a cross-platform development library designed to provide low-level access to audio, keyboard, mouse, joystick, and graphics hardware via \gls{opengl} and \gls{d3d}. It is used by video playback software, emulators, and popular games, including Valve's award-winning catalog and many Humble Bundle games.''} \gls{sdl2} is written in the C programming language, and therefore, structs and functions are used instead of objects and methods. The advantages of \gls{sdl2} are:\noparbreak \begin{itemize} \item Controller support is provided. \item 2D and 3D rendering are supported. \item Broad multiplatform support is offered, including older consoles such as the Wii. \item Low-level control is available. \item A large community ensures wide usage. \item Extended libraries can be used to add functionalities, such as SDL\_Mixer for sound. \end{itemize} The disadvantages of \gls{sdl2} are:\noparbreak \begin{itemize} \item A limited built-in 2D renderer is provided. \item Extended libraries require setup. \end{itemize} \paragraph{SFML} \gls{sfml} is a simple framework consisting of five modules: audio, graphics, network, system, and window. This framework, written in C++, was designed to simplify game development. The advantages of \gls{sfml} are: \begin{itemize} \item Object-oriented design is provided since it is written in C++. \item A built-in 2D renderer is available for ease of use. \item A built-in audio system is included. \item Cross-platform support is available for Linux, Windows, and macOS. \item Networking capabilities are provided for multiplayer or networked applications. \end{itemize} The disadvantages of \gls{sfml} are: \begin{itemize} \item The 2D rendering engine may experience performance issues in large-scale games. \item The community is smaller compared to \gls{sdl2}. \item No native 3D support is provided. \item Not all image formats are supported. \end{itemize} \subsubsection{Audio} for audio some options could be: FMOD, Wwise, or iirKlang \subsection{Conclusion} \section{Resource manager} \subsection{Introduction} \subsection{Findings} \subsection{Conclusion} \section{Rendering} \subsection{Introduction} \subsection{Findings} \subsection{Conclusion} \section{Event manager/game loop} \subsection{Introduction} \subsection{Findings} \subsection{Conclusion} % TODO: this entire section \section{Profiling and debugging} % Which profiling and debugging features are wanted? % How to provide those profiling and debugging features? % Can most of the profiling/debugging be handled by external tools? % Ideas: % - flame graph % - watchtable (combine w/ fps/speed control overlay?) % - debug printing utility functions \subsection{Introduction} \subsection{Findings} \subsubsection{Callgrind} \begin{comparison} \pro{Source code does not need to be modified for profiling} \con{Execution speed is severely impacted} \end{comparison} \subsection{Conclusion} % TODO: this entire section \section{Audio} % should audio research be scoped down to SDL2 (if that's what we're going with) or % standalone libraries only (for modularity?). The game engine is required to have an audio system with support for playing multiple audio streams (i.e.~tracks or samples) simultaniously. Since writing a custom live audio mixing engine is outside the scope of this project, this section compares various standalone audio engines that could be used in the engine. % TODO: requirements first! % REQ ~ is cross-platform % REQ ~ supports multiple audio formats (TODO: which) % REQ ~ supports simultanious playback / mixing % REQ ~ has an open-source license \begin{table} \centering \begin{tabular}{llc} \toprule \textbf{Library} & \textbf{License} & \textbf{API}\\ \midrule miniaudio & MIT-0 & C\\ YSE & EPL & C++\\ SoLoud & Zlip/LibPng & C++\\ \bottomrule \end{tabular} \caption{Audio engine library comparison} \label{tab:audio-engines} \end{table} % TODO: ref https://miniaud.io/ % TODO: ref https://www.attr-x.net/yse/ Not considered further: \begin{description} \item[FMOD] is proprietary \item[PortAudio] requires manual mixing \end{description} \section{Physics} \subsection{Introduction} \subsection{Findings} \subsection{Conclusion} \section{Scripting} \subsection{Introduction} \subsection{Findings} \subsection{Conclusion} \section{Audio} \subsection{Introduction} \subsection{Findings} \subsection{Conclusion} \section{Gameobjects/components} \label{sec:Gameobjects/components} \subsection{Introduction} One of the requirements of our customer, is that the game engine's structure is similar to Unity. The customer has created a class diagram of the game engine's API, which is (of course) very similar to Unity. One of the most important parts of the class diagram is a so-called gameObject (with several components). It's needed to understand the exact meaning/function of these gameObjects, that's why this research question arose. \subsection{Findings} A gameObject is the most important concept in Unity. Every object in a game is a GameObject, from characters and collectible items to the lights, cameras and special effects. However, a gameObject itself can't do anything on its own. A gameObject needs to be given properties before it can become a character, an envirnment, or a special effect. \autocite{man:unityGameobjects} A gameObject can be seen as a container for components. Components are the properties of the gameObject. A few examples of components are sprites, animators, audioSources, and so on. Multiple (different) components can be assigned to a single gameObject (e.g.~a sprite and an audioSource). Since we now know that a gameObject needs components to do something, it's obvious that there should be a way to add components to a gameObject. Some components (e.g.~the behaviorScript component) should also be able to reference to its gameObject. Each gameObject always has one transform class. The transform class describes the position, rotation, and scale within the scene. Some component use this information to e.g. scale a sprite. Other components eddit this information to e.g.~model gravity. \autocite{man:unityTransformClass} A gameObject can have one (or multiple) children gameObject(s). All children gameObjects, of course, also have one transform class. However, the position, rotation, and scale of this class, is always the same as the child's parent. A child can not have more than one parent. \autocite{man:unityTransformClass} \subsection{Conclusion} \section{AI} \subsection{Introduction} \subsection{Findings} \subsection{Conclusion} \end{document}