BenMakesGames.PlayPlayMini 2.2.0

Prefix Reserved
There is a newer version of this package available.
See the version list below for details.
dotnet add package BenMakesGames.PlayPlayMini --version 2.2.0                
NuGet\Install-Package BenMakesGames.PlayPlayMini -Version 2.2.0                
This command is intended to be used within the Package Manager Console in Visual Studio, as it uses the NuGet module's version of Install-Package.
<PackageReference Include="BenMakesGames.PlayPlayMini" Version="2.2.0" />                
For projects that support PackageReference, copy this XML node into the project file to reference the package.
paket add BenMakesGames.PlayPlayMini --version 2.2.0                
#r "nuget: BenMakesGames.PlayPlayMini, 2.2.0"                
#r directive can be used in F# Interactive and Polyglot Notebooks. Copy this into the interactive tool or source code of the script to reference the package.
// Install BenMakesGames.PlayPlayMini as a Cake Addin
#addin nuget:?package=BenMakesGames.PlayPlayMini&version=2.2.0

// Install BenMakesGames.PlayPlayMini as a Cake Tool
#tool nuget:?package=BenMakesGames.PlayPlayMini&version=2.2.0                

Buy Me a Coffee at ko-fi.com

What Is It?

PlayPlayMini is an opinionated framework for making smallish games with MonoGame.

It provides a state engine with lifecycle events, a GraphicsManager that provides methods for easily drawing sprites & fonts with a variety of effects, and dependency injection using Autofac.

If you don't know what all of those things are, don't worry: they're awesome, and this readme will show you how to use them (with code examples!), and explain their benefits.

What Does "Opinionated" Mean?

It means the framework has some hard requirements about how you architect your code. For example, PlayPlayMini doesn't just provide a state engine, it DEMANDS that you use it.

Some examples you may have run into:

Type Opinionated Unopinionated
HTTP server ASP.NET, Symfony Express
web client Angular, Vue React, jQuery

If you've never used opinionated frameworks before, it can sometimes feel like they're getting in your way until you understand how they work, and why they're doing what they're doing. When an opinionated framework feels this way, it's often because it has already solved the problem you're trying to solve, but you just haven't yet learned the framework's solution.

There are pros and cons to using opinionated frameworks:

Opinionated frameworks are lame when:

  • You already have a strong understanding of the underlying technologies (MonoGame, Autofac, etc), and don't need someone to tell you how to structure your application.
  • You've made games with MonoGame before, and can easily copy-paste/modify old projects into new games. (You already have an opinionated framework: one you wrote yourself!)
  • You've coded a lot, but never worked with an opinionated framework before. For a while, you'll probably find yourself butting heads with the framework, screaming "just let me do this how I always do it!"

Opinionated frameworks are great when:

  • You, or others on your team, aren't aware of best-practices and design patterns, such as dependency injection. The framework is already using these things, and tries its best to make using them easy and automatic!
  • You're writing something quick, and don't want to waste time implementing basic features like a state engine, font sheets, zoom levels for chunky pixels, etc.
  • You've never written something with the underlying technologies before (in this case, MonoGame). A good opinionated framework makes it easy to use the best features of its underlying technology.

Is PlayPlayMini a good opinionated framework? I can only say that I've tried my best to make it one!

Documentation; How to Use PlayPlayMini

Create a New MonoGame Project

  1. Create a new MonoGame project using the dotnet CLI, or Visual Studio template.
  2. Add the BenMakesGames.PlayPlayMini NuGet package.
  3. Delete the default Game1.cs. We don't need or want it.
  4. Create your first game state (more on this in a sec)
  5. Rewrite the default Program.cs (more on this later)

(PlayPlayMini project templates are also available - https://github.com/BenMakesGames/PlayPlayMiniTemplates - but for the purposes of this readme, we're gonna build things a little more from scratch!)

Game States

A "game state" is something like "the title menu", "exploring a town", "lock-picking mini-game", etc.

In PlayPlayMini, you are always in at least one game state. Let's make one:

// you don't HAVE to put your GameStates in their own folder/namespace, but it helps keep things tidy:
namespace MyGame.GameStates;

// it's common to have a game state for starting up your game. later, when you're loading TONS of
// assets, you can show some loading animation here to keep your users entertained while they wait.
// GameState is required for any game state class. bonus: it's recommended to seal most classes,
// for better performance (search the internet to learn more about this).
sealed class Startup : GameState
{
    private MouseManager Mouse { get; }
    private GameStateManager Game { get; }

    // if you're not familiar with "dependency injection", don't worry about the details too much,
    // but basically, if something in the game "wants" a class, like the MouseManager here, you
    // simply it as an arguments in the constructor, and it magically gets them. YOU'LL never
    // write "new Startup(...)"; it's all handled automatically by PlayPlayMini (via Autofac).
    public Startup(MouseManager mouse, GameStateManager game)
    {
        Mouse = mouse;
        Game = game;
    }

    // Enter() is automatically called when the player first enters this game state
    public override void Enter()
    {
        // the MouseManager requires some setup before it can be used for the first time.
        // this is a great opportunity to do it. this assumes you've actually loaded an image
        // called "Cursor"; more on how this is done, later!
        Mouse.UseCustomCursor("Cursor", (3, 1));

        // we have nothing to wait for, so let's just GET STARTED by going to the TitleMenu
        Game.ChangeState<TitleMenu>();
    }

    // the following methods are lifecycle events provided by GameState. let's go over them:

    // the "Active" methods are only called when this game state is "in the foreground". If
    // the player is in multiple game states at once, only one is "active". this is useful, for
    // example, if you have a "Pause" game state, and want to see the previous game state behind
    // it. there's an example of how to do this, later.
        
    public override void ActiveDraw(GameTime gameTime)
    {
        // in my experience, ActiveDraw doesn't get used much, EXCEPT: this is definitely
        // where you should draw any input cursors you may be using, like the mouse cursor:

        Mouse.Draw(gameTime);
    }

    public override void ActiveUpdate(GameTime gameTime)
    {
        // ActiveUpdate is where you'll put most of your logic for most of your game states.
    }

    public override void ActiveInput(GameTime gameTime)
    {
        // this is where you'll get mouse and/or keyboard input.
    }

    // the "Always" methods are always called for the current/active game state. later on,
    // there's an example of how to call them for "background" game states.
        
    public override void AlwaysDraw(GameTime gameTime)
    {
        // most of your drawing logic will go here.
    }

    public override void AlwaysUpdate(GameTime gameTime)
    {
        // if you've got animated things, like maybe animated water tiles in a tile-based RPG,
        // you might want to keep those animations going even while the state is "inactive",
        // for example while a pause screen is up. AlwaysUpdate is the place to put such
        // logic.
    }

    // there is no "AlwaysInput".
}

There's a few things to unpack in that example:

First of all, if you understand what all the methods in GameState are for, then you're probably starting to get a sense for how your application will be structured: a series of game states, which the player will move between according to some logic.

Second, you may have noticed:

Game.ChangeState<NEW_GAME_STATE_CLASS_NAME_HERE>();

The GameStateManager's ChangeState method is how you'll be moving between game states. There are a couple ways to call it; more on these later.

Third: that whole "dependency injection" thing. What's that about?

A Brief Aside: Dependency Injection

Feel free to skip/skim this section if you're like "yes, I know all about IoC/DI. I even know all the acronyms."

I mentioned before that you'll never call new SomeGameState(...), which may feel weird to you. This is one of the main features of "dependency injection", provided by the library Autofac, which PlayPlayMini uses under the hood.

For example, this line:

public Startup(MouseManager mouse, GameStateManager game)

Here, the Startup class is saying "I want a MouseManager, and I want a GameStateManager"; ordinarily, you'd have to provide those when you call new Startup(...), but again, with dependency injection, you never write "new Startup(...)"!

But if you never write new Startup(...), how does one ever get made?!

Hold that thought. Let's take a moment to look at some of the advantages of never writing new.

Advantages of Dependency Injection Frameworks

First: as your game states grow in number and complexity, you'll want to give them more and more "services" like the GraphicsManager, FrameCounter, and others you make yourself. If you were newing up the game states "manually", then every time you added a new service to a constructor, you'd have to find all the places you made a new one, and give them the new things they need.

new Startup(new MouseManager(...???), new GameStateManager(?!!?!?));

If you've ever found yourself doing that, a DI framework can help.

Second: if you new up a game state manually, and it needs a MouseManager, you'd also have to create a new MouseManager() for it... but what if the MouseManager's constructor also has arguments? Now you'll have to new up those, too! Again: with a DI framework, you never write new, so you don't have to do any of this!

Third: Many services, like the example MouseManager, you really only need one of. You want to use the same instance over and over. You can write global statics (more on why these are bad in a moment), but Dependency Injection frameworks, like Autofac, can be configured to find an existing instance of a service class, and use that instead of making a new one, and you don't have to write any extra code to get that functionality.

Fourth: no more global static singletons, or hand-writing lazy instantiation logic! As a project grows, if you make a lot of global statics, it takes great care to prevent your application from becoming less efficient, with longer startup times and higher memory usage, and it becomes harder to maintain: bugs creep in more easily and more often. Of course, no one library can instantly solve all those problems, but dependency injection frameworks solve a good chunk of them! If you've ever written an application brimming with globals, and found yourself spending a lot of time fixing bugs with them, DI frameworks are here to make your life easier!

So how do you create a new service without writing new? Search the interwebs if you want more details, but to put it simply: the dependency injection framework just does it for you. If Startup asks for a MouseManager, then the DI framework gives it one. To do so, those classes just have to be registered with the DI framework. (More on how to register classes, later!)

Learn More

Rewriting Program.cs

Alright, so you've made a game state - maybe more; maybe you've even put some logic in - but how do you tell MonoGame which game state to start up with?

For that, open up the default Program.cs. You need to completely rewrite it... but don't worry: it's pretty easy!

using BenMakesGames.PlayPlayMini; // don't forget this part!
using MyGame.GameStates; // assuming you put your game state classes here
using System;

// with PlayPlayMini, we use the GameStateManagerBuilder to get things started.
var gsmBuilder = new GameStateManagerBuilder();

gsmBuilder
    .SetInitialGameState<Startup>() // define the starting game state
    .SetWindowSize(480, 270, 2) // 480x270, with a x2 zoom level (window will be 960x540)
    .AddAssets(new IAsset[]
    {
        // immediately loaded
        new PictureMeta("Loading", "Graphics/Loading", true),
        new PictureMeta("Cursor", "Graphics/Cursor", true),

        // deferred
        new PictureMeta("Terrain", "Graphics/Terrain"),
        new PictureMeta("Title", "Graphics/Title"),
        new PictureMeta("TitleBackground", "Graphics/TitleBackground"),
        new SpriteSheetMeta("Treasure", "Graphics/Treasure", 16, 16),
        new SpriteSheetMeta("TerrainTrim", "Graphics/TerrainTrim", 10, 10),
        new FontMeta("Font", "Graphics/Font", 6, 8)
    })
;

// once we're done configuring, we're ready to go!
gsmBuilder.Run();

Taking it one step at a time:

var gsmBuilder = new GameStateManagerBuilder();

We talked about all that fancy dependency injection stuff, but here we are, newing something up manually!

The dependency injection system has to get started somehow. That's actually one of the jobs of the GameStateManagerBuilder.

(Also, if you're new to DI, only objects filled with "business logic" get registered with DI. Data-only objects like PictureMeta should still be newed up manually, and should never ask for a service in their constructor.)

.SetInitialGameState<Startup>() // define the starting game state
.SetWindowSize(480, 270, 2) // 480x270, with a x2 zoom level (window will be 960x540)

Hopefully those are pretty self-explanatory. The final 2 in SetWindowSize indicates that all pixels should actually be drawn as 2x2 pixels. Under the hood, PlayPlayMini upscales your graphics, yielding a chunky pixel look! Set the zoom level to 1 if don't want chunky pixels!

Next up:

.AddAssets(new IAsset[] {
    ...
})

This method tells the GraphicsManager (and SoundManager) which assets to load, from your Content/Content.mcgb file. Content/Content.mcgb is part of MonoGame's asset "pipeline". PlayPlayMini hides a lot of MonoGame's internals, but the asset pipeline isn't something that can be - or should be - hidden! It's how you tell MonoGame what graphics, sounds, and songs, your game will use.

If you've never used the Content/Content.mgcb file before, check out MonoGame's documentation on the subject:

It's a super-useful tool!

Moving on:

// immediately loaded
new PictureMeta("Loading", "Graphics/Loading", true),
new PictureMeta("Cursor", "Graphics/Cursor", true),

// deferred
new PictureMeta("Terrain", "Graphics/Terrain"),

PictureMeta (along with SpriteSheetMeta and FontMeta) is a struct that contains everything the GameManager service needs to load and store graphics.

The first argument is the name/key/ID/whatever-you-wanna-call-it which you're assigning to the image. It can be anything, and spaces and other punctuation are allowed, if you want/need them (it's just a string, after all!) You'll refer to this later, when drawing images.

The second argument is a path to the image, matching your Content/Content.mgcb file's definition of the image.

The third, optional argument tells the GraphicsManager whether it needs to load the image up before doing ANYTHING else. The default is to load the images in the background while the game continues to run.

From the example above, we're saying that the "Loading" and "Cursor" graphics needs to be available immediately (presumably to be displayed on a loading screen), while the other images can load in later.

Checking if All Graphics have been Loaded

If your project has any deferred images, you need to make sure to wait for them to be loaded before continuing.

Let's modify the Startup game state class from before to check for this, and move on to the title menu only once all the graphics are ready!

namespace MyGame.GameStates;

sealed class Startup : GameState
{
    private MouseManager Mouse { get; }
    private GameStateManager Game { get; }
    private GraphicsManager Graphics { get; }

    // the GraphicsManager knows whether or not it's loaded everything up. BEHOLD THE POWER OF
    // DEPENDENCY INJECTION: we decided we need the GraphicsManager, so we just ask for it.
    public Startup(MouseManager mouse, GameStateManager game, GraphicsManager graphics)
    {
        Mouse = mouse;
        Game = game;
        Graphics = graphics;
    }

    public override void Enter()
    {
        Mouse.UseCustomCursor("Cursor", (3, 1));

        // we shouldn't do this immediately anymore!
        //Game.ChangeState<TitleMenu>();
    }

    public override void ActiveDraw(GameTime gameTime)
    {
        // since we have the GraphicsManager, let's ask it to draw the "Loading" image.
        // I'm putting it in the very upper-left - 0, 0 - which is kinda' boring. Sorry.
        GraphicsManager.DrawSprite(GraphicsManager.Pictures["Loading"], 0, 0);
            
        Mouse.Draw(gameTime);
    }

    public override void ActiveUpdate(GameTime gameTime)
    {
        // okay! let's check if the graphics are all loaded, and move on only when they are!
        if(Graphics.FullyLoaded)
            Game.ChangeState<TitleMenu>();
    }

    // the rest of the lifecycle methods can be deleted; we're not using them!
}

It's important to note: if you try to use a graphic before it's loaded, your application will crash, so don't do it!

If you also have deferred sound effect or music assets, inject the SoundManager, and check on its FullyLoaded property, as well!

Services

If you're familiar with DI, you already know this, but you can create your own services. A service is just any class that's been registered with the DI framework (Autofac, in our case). Suppose you make a ParticleEffectService class... once your register it as a service, you can ask for a ParticleEffectService in the constructor of any other class, and you can ask for other services in the constructor of your ParticleEffectService.

See "Creating Your Own Services" below for more info, as well as tips on how to avoid "circular dependencies" (instances where two services request one another in their constructors!)

For now, here are the service built into BenMakesGames.PlayPlayMini:

Built-in Services

GameStateManager

The GameStateManager is needed to change the game's state, for example to transition from your title menu to your load screen, etc.

Most of your game states will probably include the GameStateManager as one of their dependencies.

GraphicsManager

The GraphicsManager has methods for drawing graphics and fonts.

Most of your game states will probably include the GraphicsManager as one of their dependencies.

SoundManager

The SoundManager has methods for playing sounds and looping music.

It uses MonoGame's built-in sound library, which has some limitations, and even some audible bugs on some platforms (such as poor looping of music tracks on Windows).

If/when you get your game to a good state, and you really want to upgrade your game's sound and music, I recommend finding a C# FMOD library, like https://github.com/Martenfur/ChaiFoxes.FMODAudio. You'll have to hook it manually; I recommend creating your own sound manager service to wrap it up!

I'm working on an "official" FMOD package for PlayPlayMini, but don't currently have an ETA. If you beat me to the punch, let others (and me) know!

KeyboardManager

You can use still MonoGame's Keyboard class directly; the KeyboardManager provides some additional features, like checking whether or not a particular key was JUST pressed (without having to write checks for that yourself).

Whether or not you use this class really depends on the kind of game you're making, and whether or not you want to/need to write your own keyboard controls.

MouseManager

You can use still MonoGame's Mouse class directly; the MouseManager provides some additional features, including a method for drawing a custom cursor, and disabling the mouse when there's keyboard activity.

Whether or not you use this class really depends on the kind of game you're making, and whether or not you want to/need to write your own mouse controls.

If you're using the BenMakesGames.PlayPlayMini.UI extension package, the MouseManager becomes a requirement.

FrameCounter

The FrameCounter counts FPS, and some other stats. Use it if you want to add an FPS indicator on the screen.

Creating Your Own Service

Once you've created your class, there are two ways you can register it with Autofac + PlayPlayMini:

Registering a Service Manually, in Program.cs

One of the methods you can call on the GameStateManagerBuilder is AddServices. If there isn't already a call to it, add one; it would look something like this:

gsmBuilder
	... // loading graphics, etc
    .AddServices(s => {
        s.RegisterType<MyService>();
        s.RegisterType<SomeOtherService>();
    })
    ... // loading graphics, etc
;

If RegisterType doesn't seem to be available, add using AutoFac; to the top of the file. Your IDE should be nice and suggest this for you.

You can also use this method to register classes you didn't write! For example, PlayPlayMini already registers Random as a service, so any of your services (or game states) can ask for a Random in their constructor.

For more info on how to register services, check the Autofac documentation: https://autofac.org

Registering a Service Automatically, Using the AutoRegister Attribute

PlayPlayMini provides an attribute called AutoRegister which you can attach to a class to register that class with Autofac. When the game starts up, it searches for all classes using this attribute, and registers them for you! This attribute doesn't provide all of the options available when registering manually, but the vast majority of services don't use these options.

If you don't need to do anything fancy with your service registration, just add the AutoRegister attribute. It requires a Lifetime argument, and optionally allows an InstanceOf property.

As an example of the most basic use case:

[AutoRegister(Lifetime.Singleton)]
sealed class MyService
{
	...
}

Possible lifetimes are:

  • Lifetime.Singleton
    • When a service uses this lifetime, then only one instance of the service class will ever be created. Any and all services requesting a singleton service will receive the same instance.
    • This is probably the behavior you want for most of your services.
  • Lifetime.PerDependency
    • When a service uses this lifetime, then a new instance of the service class is created each time the service is requested.
    • This is useful for services which contain internal state that you want reset with every use. For example, game states are registered this way: every time you ask for a game state, you get a new copy of that game state.
    • Only use this lifetime if you're sure you need it; otherwise, use Lifetime.Singleton.
How and When to Use InstanceOf

Here's a rough example showing how you would use the InstanceOf property of AutoRegister:

// first, an interface
interface IRandomNumberGenerator
{
    int RandomInt(int inclusiveMin, int inclusiveMax);
}

// the class which implements that interface:
[AutoRegister(Lifetime.Singleton, InstanceOf = typeof(IRandomNumberGenerator))]
sealed class MyRNG: IRandomNumberGenerator
{
	public int RandomInt(int inclusiveMin, int inclusiveMax)
    {
    	...
    }
}

// this game state wants some kind of IRandomNumberGenerator; it doesn't know
// (or care) that it will get an instance of MyRNG:
sealed class SomeGameState: GameState
{
    private IRandomNumberGenerator RNG { get; }
    
    public SomeGameState(IRandomNumberGenerator rng)
    {
    	RNG = rng;
    }
    
    public bool LandedHit(int percentChanceToHit)
    {
    	return RNG.RandomInt(1, 100) <= percentChanceToHit;
    		return false;
    }
}

You could easily do without the IRandomNumberGenerator interface this example, so why/when should you go through the trouble? There are a few reasons, including:

  • When your service implements an interface provided by a third-party library.
  • When writing unit tests, interfaces can be mocked (for example, with the NSubstitute library). If you decide to write unit tests, you will need to add interfaces for the services which you want to mock.

Dealing with Circular Dependencies

A circular dependency is when two services refer to one another in their constructors. Ex:

[AutoRegister(Lifetime.Singleton)]
sealed class ServiceA
{
    public ServiceA(ServiceB b)
    {
        ...
    }
}

[AutoRegister(Lifetime.Singleton)]
sealed class ServiceB
{
    public ServiceB(ServiceA a)
    {
        ...
    }
}

If you write code like this, Autofac will complain (and crash) when it tries to instantiate a service that requests either ServiceA or ServiceB.

This can be resolved in two ways:

  1. Create a new service, ServiceC, that services A and B depend on, instead of depending on one another. Move the method or methods needed into ServiceC, and update your code accordingly.
  2. Register either ServiceA or ServiceB as a lazy service. There are a few ways to do this; one is to use this NuGet package: https://github.com/servicetitan/lazy-proxy-autofac
    1. When registering services as lazy services, you'll have to manually register them; you can't use AutoRegister for quick registration.

Advanced Services Configuration: Service Lifetime Events

There are several interfaces which services can implement, each allowing the service to hook into different processes within PlayPlayMini. A service may implement any combination of this interfaces, or none at all. They are:

  • IServiceDraw
    • The service class must implement a Draw method, which will be called after the current state's AlwaysDraw and ActiveDraw events have been called.
    • An example service which implements this interface is the built-in FrameCounter service, which displays the FPS on-screen.
  • IServiceInitialize
    • The service class must implement an Initialize method, which will be called at the beginning of the MonoGame Initialize state, before MonoGame's LoadContent method is called.
  • IServiceInput
    • The service class must implement an Input method, which will be called before the current state's Input event.
    • Example services which implements this interface are the built-in KeyboardManager and MouseManager.
  • IServiceLoadContent
    • The service class must implement a LoadContent method, and FullyLoaded getter. The LoadContent method is called in MonoGame's LoadContent method. It's up to the service class's author to implement FullyLoaded accurately (probably as public bool FullyLoaded { get; private set; }, setting it to true when LoadContent has completed).
  • IServiceUpdate
    • The service class must implement an Update method, which will be called before the current state's AlwaysUpdate and ActiveUpdate methods.

More Game State Stuff

Multiple States at Once

Here's how you can draw two states at once, for example, to show a pause screen on top of another game state:

public sealed class PauseScreen: GameState
{
	public GameState PreviousState { get; }
    
    ...
    
    public PauseScreen(..., GameState previousState)
    {
    	...
    	
    	PreviousState = previousState;
    }
    
    public override void AlwaysDraw(GameTime gameTime)
    {
    	PreviousState.AlwaysDraw(gameTime);
    	
    	// rest of drawing logic here, for example:
    	GraphicsManager.DrawFilledRectangle(0, 0, GraphicsManager.Width, GraphicsManager.Height, new Color(0, 0, 0, 0.8));
    	
    	GraphicsManager.DrawPicture("Paused", 100, 200);
    }
    
    public override void AlwaysUpdate(GameTime gameTime)
    {
    	PreviousState.AlwaysUpdate(gameTime);
    	
    	// pause screen's own update logic goes here, if any
    }
    
	public override void ActiveInput(GameTime gameTime)
    {
        // press Escape to un-pause
    	if(KeyboardManager.PressedKey(Keys.Escape))
        {
            // we have a reference to a GameState, so we can invoke ChangeState this way:
        	GameStateManager.ChangeState(PreviousState);
        }
    }
    
    ...
}

The pause screen would then be opened like this:

public sealed class CombatEncounter: GameState
{
	...
	
	public override void ActiveInput(GameTime gameTime)
    {
    	...
    	
    	if(KeyboardManager.PressedKey(Keys.Escape))
        {
        	GameStateManager.ChangeState<PauseScreen, GameState>(this);
        }
    }
    
    ...
}

By the way, this ChangeState method can be used to pass more complex parameters to a game state, too. For example, assuming you have some PauseScreenConfig class, you might write:

GameStateManager.ChangeState<PauseScreen, PauseScreenConfig>(new PauseScreenConfig() {
	PreviousState = this,
	BackgroundOpacity = 0.5f,
	PausePicture = "Pause",
});

Game State Lifecycle Events Summary

A game state's lifecycle event methods are called, in this order.

  1. Enter
    • Called when the game state is entered into.
    • Do any first-time setup needed for the game state, ex: initializing a star field array.
  2. ActiveInput
    • Always called for the current game state.
    • Handle user input here. Ex: see that the player is pressing up, and set a property on the player indicating that they'd like to move up.
  3. AlwaysUpdate
    • Always called for the current game state.
    • Do decorative logic here, such as updating passive particle effects and animations (ex: animated water tiles in a tile-based game).
    • If you have two states running simultaneously, the active state's AlwaysUpdate should call the background state's AlwaysUpdate. You will have to do this manually.
  4. ActiveUpdate
    • Always called for the current game state.
    • Do game logic here, such as moving the player (or not, if they're blocked), enemies, etc.
  5. AlwaysDraw
    • Always called for the current game state.
    • Do main drawing logic here: backgrounds, player, enemies, particles, etc.
    • If you have two states running simultaneously, the active state's AlwaysDraw should call the background state's AlwaysDraw first thing! You will have to do this manually.
  6. ActiveDraw
    • Always called for the current game state.
    • Draw things you only want drawn if the game is the foreground state, for example the mouse cursor (MouseManager's ActiveDraw).
  7. Leave
    • Called if a new game state is replacing the current game state.
    • Immediately after Leave is called, the current game state is changed to be the next game state.
    • I haven't yet found a use for this method; it's included for completeness/just-in-case.
Product Compatible and additional computed target framework versions.
.NET net6.0 is compatible.  net6.0-android was computed.  net6.0-ios was computed.  net6.0-maccatalyst was computed.  net6.0-macos was computed.  net6.0-tvos was computed.  net6.0-windows was computed.  net7.0 was computed.  net7.0-android was computed.  net7.0-ios was computed.  net7.0-maccatalyst was computed.  net7.0-macos was computed.  net7.0-tvos was computed.  net7.0-windows was computed.  net8.0 was computed.  net8.0-android was computed.  net8.0-browser was computed.  net8.0-ios was computed.  net8.0-maccatalyst was computed.  net8.0-macos was computed.  net8.0-tvos was computed.  net8.0-windows was computed. 
Compatible target framework(s)
Included target framework(s) (in package)
Learn more about Target Frameworks and .NET Standard.

NuGet packages (4)

Showing the top 4 NuGet packages that depend on BenMakesGames.PlayPlayMini:

Package Downloads
BenMakesGames.PlayPlayMini.UI

An extension for PlayPlayMini, adding a skinnable, object-oriented UI framework.

BenMakesGames.PlayPlayMini.GraphicsExtensions

Some GraphicsManager extensions for PlayPlayMini.

BenMakesGames.PlayPlayMini.BeepBoop

An extension for PlayPlayMini which adds methods for generating & playing simple waveforms.

BenMakesGames.PlayPlayMini.NAudio

Get seamless looping music, and cross-fade, in your MonoGame-PlayPlayMini game using NAudio.

GitHub repositories

This package is not used by any popular GitHub repositories.

Version Downloads Last updated
5.2.0 114 9/1/2024
5.1.0 111 8/18/2024
5.0.0 147 8/17/2024
4.7.1 139 5/28/2024
4.7.0 136 5/24/2024
4.6.2 128 4/25/2024
4.6.1 110 4/21/2024
4.6.0 108 4/21/2024
4.5.0 198 3/23/2024
4.4.0 145 3/2/2024
4.3.0 131 2/25/2024
4.2.0 141 2/22/2024
4.1.0 140 2/12/2024
4.0.1 253 11/25/2023
4.0.0 149 11/25/2023
3.3.0 192 10/28/2023
3.2.0 129 10/27/2023
3.1.1 198 10/25/2023
3.1.0 156 10/21/2023
3.0.0 168 9/18/2023
2.7.0 173 9/17/2023
2.6.0 251 6/30/2023
2.5.0 186 5/7/2023
2.4.0 321 4/16/2023
2.3.0 377 3/11/2023
2.2.0 261 3/11/2023
2.1.1 225 3/9/2023
2.1.0 468 1/7/2023
2.0.2 364 12/11/2022
2.0.1 357 11/26/2022
2.0.0 380 11/16/2022
1.1.1 514 10/8/2022
1.1.0 596 9/24/2022
1.0.0 636 9/14/2022
0.10.1 459 9/5/2022
0.10.0 583 5/12/2022
0.9.1 466 4/5/2022
0.9.0 627 1/15/2022