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Ninja Battle

Ninja Battle is a deterministic multiplayer online game made in Unity that implements basic rollback, intended for use as a example project of different technologies that Nakama offers.

Genre: Action PvP

Players: 2 to 4 players

Game engine: Unity 2021.1.18f1

Language: C# for Unity, Typescript for Nakama

Platform: PC, Mac and Web

Multiplayer: Nakama server authoritative

Server logic: Manage score and rounds

Client logic: Send inputs on a deterministic simulation and implement a simple rollback

Gameplay: You play as a ninja that has to battle against other player-controlled ninjas. When a ninja moves, they leave behind a caltrops path that makes the terrain deadly even for themselves. The ninjas cannot stop moving. You can only control the direction that the ninja is moving in. A single touch to the caltrops eliminates you. The ninja can prevent the damage by jumping over the caltrops automatically. If the ninja runs against a wall or falls into caltrops, he is eliminated instantly. If two ninjas run into each other, both are eliminated.

Screenshots

image image image image

Feel free to contribute

This is an open source project, all contributions are welcome, if you want to contribute you can create and issue first and we can discuss the changes or the features you want to add in there.

Nakama Helpers

The Nakama Helpers are a small library of functions I made intended to be used on any project that uses Nakama, it helps to develop easier or as an example of how to do certain things. Eventually I want to create their own repository and link it with this one, they are not official Nakama utilities.

Set Up Nakama

The easiest way to start with Nakama is with docker, the Nakama documentation offers a nice guide on how to do this, the server code on this repository is on TypeScript so it requires installing the TypeScript support too, here's the official documentation on how guide to do this.

Understanding rollback netcode

The rollback netcode is a type of netcode that uses deterministic simulations on each of the clients and works sending their inputs to the others with the information of the exact time it ocurred, the simulation does not wait for the inputs of other users, but if in a determined moment a message is received with an previous time than the actual time of the simulation the simulation should be able to go back in time, handle the inputs and fastforward to the current time.

There's an awesome article that explains how the rollback netcode works here.

Unity structure

The game consist of 7 scenes, numbered from 0 to 6, each scene handle different moments of the application.

Scene Logic
0-Initializer Initialize all singletons, this scene is run only once per session.
1-Splash Handles the Nakama login.
2-Home Main menu of the app in here you can see your trophies, change your name and start a match
3-Lobby The lobby where you wait for another players, in this scene you are already on a match.
4-Battle This is where the gameplay occcurs.
5-RoundResults Shows how many rounds each player has won.
6-FinalResults Show the winner of the game.

Nakama Manager

NakamaManager is the base script of all the Nakama Helpers, on this script you can Login and Logout and send RPC to the server.

Login

The current state of NakamaManager handles 3 types of login:

  • LoginWithUdid - It generates a random UDID and saves it to the players prefs. Recommended for WebGL since it is impossible to obtain a device ID.
  • LoginWithDevice - Uses the device unique identifier to handle the login. Recommended for mobile devices.
  • LoginWithCustomId - Uses a string to handle the authentication, recommended for use for testing on the editor.

To call them you just have to reference the instance of NakamaManager and call the function you want, for example on the scene 1-Splash on the script NakamaÀutoLogin it's called like this:

NakamaManager.Instance.LoginWithUdid();

You can hear the response suscribing to the events of NakamaManager After the login is executed you can subscribe to It has various events you can subscribe to handle your game logic. You can use the component "NakamaEvents" that exposes all the NakamaManager events to the unity inspector, you can see an example on the scene 1-Splash on the prefab ChangeSceneOnLogin that after receiving an login success it executes the ChangeScene action of the SceneChanger.

Set up a name

The functionality of setting up a name can be found on the script SetDisplayName and on NakamaUserManager. On this game we wanted for the players to join a match as soon as possible so if a player don't want to set up a customized name a name will be automatically generated using a combination of two predefined words, this will be done just as soon as the user information is loaded, if there's no name assosiated to that account one will be generated or if its already one it will display it on the area. Now to update the player's name we are suscribing to the ValueChanged event of the TMP_InputField that each time that it triggers a countown starts so on the moment the player stops typing the name will be saved on the Nakama server, the actual saving of the name is done on the NakamaUserManager on the function `UpdateDisplayName``

public async void UpdateDisplayName(string displayName)
{
    await NakamaManager.Instance.Client.UpdateAccountAsync(NakamaManager.Instance.Session, null, displayName);
}

Joining a lobby

The lobby feature consists on two parts one is handled via the unity client and other from a custom rpc call on the nakama server, lets follow the logic: 1- The player presses the Battle button that triggers the MultiplayerJoinMatchButton component function FindMatch:

private void FindMatch()
{
    button.interactable = false;
    MultiplayerManager.Instance.JoinMatchAsync();
}

2- The MultiplayerManagerregisters for the upcoming match states:

NakamaManager.Instance.Socket.ReceivedMatchState += Receive;

3- The RPC "JoinOrCreateMatchRpc" is called using the NakamaManager:

private const string JoinOrCreateMatchRpc = "JoinOrCreateMatchRpc";
...csharp
IApiRpc rpcResult = await NakamaManager.Instance.SendRPC(JoinOrCreateMatchRpc);

4- On the server the joinOrCreateMatch RPC is executed, this RPC finds one match that has still room left for another player and its still open, open reffers that the game has not started yet, and in the case that no match is found a new match will be created.

let joinOrCreateMatch: nkruntime.RpcFunction = function (context: nkruntime.Context, logger: nkruntime.Logger, nakama: nkruntime.Nakama, payload: string): string
{
    let matches: nkruntime.Match[];
    const MatchesLimit = 1;
    const MinimumPlayers = 0;
    var label: MatchLabel = { open: true }
    matches = nakama.matchList(MatchesLimit, true, JSON.stringify(label), MinimumPlayers, MaxPlayers - 1);
    if (matches.length > 0)
        return matches[0].matchId;

    return nakama.matchCreate(MatchModuleName);
}

5- Now back on the client we obtain the matchId returned by the server and send a request to join the match

string matchId = rpcResult.Payload;
match = await NakamaManager.Instance.Socket.JoinMatchAsync(matchId);

6- The onMatchJoin event gets called

onMatchJoin?.Invoke();

7- The GameManageris suscribed to onMatchJoin and switches to the 3-Lobby scene

MultiplayerManager.Instance.onMatchJoin += JoinedMatch;
...
private void JoinedMatch()
{
    ResetPlayerWins();
    GoToLobby();
}
...
private void GoToLobby()
{
    SceneManager.LoadScene((int)Scenes.Lobby);
}

Client game logic

MultiplayerManager

The MultiplayerManager is the responsable for joining a match and sending and receiving messages from and to the match on the server. To find a specific match a RPC is sent to the server that helps creating or joining a match. The specific steps can be found on the Joining a Lobby section. To receive and send messages we want to sepearate the different behaviours by using a code, you can find the codes I used for this game in MultiplayerManager.OperationCode let's take a look into each one:

Code Name Logic
0 Players Is a list with of the players including their display name, is sent by the server to the new player when a he joins the match
1 PlayerJoined Is the display name of the new player, is sent to all other players by the server when a new player joins the match
2 PlayerInput This is the direction that the player wants to move, is sent by the client to all other clients
3 PlayerWon This is when a player reported that someone won the match, every client must report the same result to the server to trust the client
4 Draw This is when a player reported that the game ended on a draw, every client must report the same result to the server to trust the client
5 ChangeScene Sent by the server to all clients to report to which scene the client should change

The MultiplayerManager is subscribed to a match state change just before joining the match like this:

socket.ReceivedMatchState += Receive;

The idea is that the MultiplayerManager will receive all the messages and distribute them to the interested behaviours. For a script to receive a message he must subscribe to the MultiplayerManager like this:

MultiplayerManager.Instance.Subscribe(MultiplayerManager.Code.PlayerInput, ReceivedPlayerInput);

All the messages received with the code you subscribed will execute the funcion you passed. To send a message you should send a object that can be serialized and the MultiplayerManager handles the serialization

private void SendData(int tick, Direction direction)
{
   MultiplayerManager.Instance.Send(MultiplayerManager.Code.PlayerInput, new InputData(tick, (int)direction));
}

To receive a message you should deserialize to the class you want, the MultiplayerMessage can do it like this

private void ReceivedPlayerInput(MultiplayerMessage message)
{
   InputData inputData = message.GetData<InputData>();
   SetPlayerInput(GetPlayerNumber(message.SessionId), inputData.Tick, (Direction)inputData.Direction);
}

Multiplayer Identity

Is a script that holds the unique id of a object or player, in this case is the SessionId of each player, if we want to have objects in the scene it could be an auto-incemented number.

Spawning players

The spawn of the players is made by the Map class on initialization, it takes each player and put each one on a spawn point

public void InstantiateNinja(int playerNumber, SpawnPoint spawnPoint, string sessionId)
{
    Ninja ninja = Instantiate(ninjaPrefab, transform);
    ninja.Initialize(spawnPoint, playerNumber, this, sessionId);
    Ninjas.Add(ninja);
    if (MultiplayerManager.Instance.Self.SessionId == sessionId)
        gameCamera.SetStartingPosition(spawnPoint.Coordinates);
}

Rollback Var

Have in mind that this is the most basic implementation of a rollback, the class RollbackVar<T> handles the save of information on a timeline, how it works is that each position and input is saved on a dictionary of an int and a T, being T any type you want, the int part represents each tick of the gameloop.

private Dictionary<int, T> history = new Dictionary<int, T>();

Server game logic

RPC

The RPC (Remote procedure call) helps send information from a client to the server when its outside a match, the registering of the RPC must be done inside of the InitModule, int his exaple is on the main TypeScript file and the RPC is located under rpcs file.

function InitModule(ctx: nkruntime.Context, logger: nkruntime.Logger, nk: nkruntime.Nakama, initializer: nkruntime.Initializer)
{
    initializer.registerRpc("JoinOrCreateMatchRpc", joinOrCreateMatch);
}

let joinOrCreateMatch: nkruntime.RpcFunction = function (context: nkruntime.Context, logger: nkruntime.Logger, nakama: nkruntime.Nakama, payload: string): string
{
    return "response";
}

On unity you can call the RPC using the client you used to create a socket:

return await client.RpcAsync(session, rpc, payload);

Match Handler

The match handler manages an match, from the lobby to the end results. Like the RPCs the registering of the match must be done inside of the InitModule, you should assign a name in this case is just called "match", the functions of each state can be found on match_handler.

function InitModule(ctx: nkruntime.Context, logger: nkruntime.Logger, nk: nkruntime.Nakama, initializer: nkruntime.Initializer)
{
    initializer.registerMatch("match", {
        matchInit,
        matchJoinAttempt,
        matchJoin,
        matchLeave,
        matchLoop,
        matchTerminate
    });
}

The match is created on the RPC joinOrCreateMatch, when creating the match a MatchId is returnes and it should be sent to the clients

nakama.matchCreate("match");

The match_handler holds all the logic of a match, all the data specific of a match will be being passed to all the match functions on a match state object, this is a dictionary and you can cast it to a interface, in this case we use a interface called "GameState"

interface GameState
{
    players: Player[]
    playersWins: number[]
    roundDeclaredWins: number[][]
    roundDeclaredDraw: number[]
    scene: Scene
    countdown: number
    endMatch: boolean
}

You can find the initialization of this state on the matchInit function

let matchInit: nkruntime.MatchInitFunction = function (context: nkruntime.Context, logger: nkruntime.Logger, nakama: nkruntime.Nakama, params: { [key: string]: string })
{
    var label: MatchLabel = { open: true }
    var gameState: GameState =
    {
        players: [],
        playersWins: [],
        roundDeclaredWins: [[]],
        roundDeclaredDraw: [],
        scene: Scene.Lobby,
        countdown: DurationLobby * TickRate,
        endMatch: false
    }

    return {
        state: gameState,
        tickRate: TickRate,
        label: JSON.stringify(label),
    }
}

Match Loop

The matchLoop is the function that gets called each tick, on each of these ticks all the client's messages sent on that period of time are received as a list, with this list you can decide what to do with the messages, to send them back to the clients or execute a custom logic.

Scenes

On this example the server behavior are separated on different logical Scenes, each scene have a different behaviour, so each tick only runs the logic of that scene. The flow of a match goes like this: Lobby -> Battle -> RoundResult -> if no player has obtained 3 victories go back to Battle, if a player has already obtained 3 victories end the match.

Custom and default messages logic

Each tick all the messages received by the clients are received by the matchLoop then they are processed on the processMessages function, if a message code has a custom logic a special fuction is called or if there is no custom logic a default logic will be eecuted, in this example the custom logics are registered on the consts file and the default logic just send the message to all the clients.

function processMessages(messages: nkruntime.MatchMessage[], gameState: GameState, dispatcher: nkruntime.MatchDispatcher): void
{
    for (let message of messages)
    {
        let opCode: number = message.opCode;
        if (MessagesLogic.hasOwnProperty(opCode))
            MessagesLogic[opCode](message, gameState, dispatcher);
        else
            messagesDefaultLogic(message, gameState, dispatcher);
    }
}

function messagesDefaultLogic(message: nkruntime.MatchMessage, gameState: GameState, dispatcher: nkruntime.MatchDispatcher): void
{
    dispatcher.broadcastMessage(message.opCode, message.data, null, message.sender);
}

Time counters

On the scenes Lobby and RoundResults the server runs countdown to wait for the next scene, you can see how it works on the Lobby scene behaviour

function matchLoopLobby(gameState: GameState, nakama: nkruntime.Nakama, dispatcher: nkruntime.MatchDispatcher): void
{
    if (gameState.countdown > 0 && getPlayersCount(gameState.players) > 1)
    {
        gameState.countdown--;
        if (gameState.countdown == 0)
        {
            gameState.scene = Scene.Battle;
            dispatcher.broadcastMessage(OperationCode.ChangeScene, JSON.stringify(gameState.scene));
            dispatcher.matchLabelUpdate(JSON.stringify({ open: false }));
        }
    }
}

The countdown is set on matchJoin when a player joins, the duration is on seconds and its multiplied to the tick rate of the server

gameState.countdown = DurationLobby * TickRate;

Determining battle winners

Since the game uses rollback there can be a erroneous message sent by a client telling who was the winner of the match, for example if there are two players remaining and a client sees a one of them hitting a wall he can determine wrongly that the player lose the battle, but is possible that the player turned just before hitting the wall, when a client determines a victory a message is sent to the server, if the server got messages of every player determining that on the same tick the same outcome then the server can trust the clients and determine who was the winner. This is done on the playerWon function.

function playerWon(message: nkruntime.MatchMessage, gameState: GameState, dispatcher: nkruntime.MatchDispatcher): void 
{
    if (gameState.scene != Scene.Battle || gameState.countdown > 0)
        return;

    let data: PlayerWonData = JSON.parse(message.data);
    let tick: number = data.tick;
    let playerNumber: number = data.playerNumber;
    if (gameState.roundDeclaredWins[tick] == undefined)
        gameState.roundDeclaredWins[tick] = [];

    if (gameState.roundDeclaredWins[tick][playerNumber] == undefined)
        gameState.roundDeclaredWins[tick][playerNumber] = 0;

    gameState.roundDeclaredWins[tick][playerNumber]++;
    if (gameState.roundDeclaredWins[tick][playerNumber] < getPlayersCount(gameState.players))
        return;

    gameState.playersWins[playerNumber]++;
    gameState.countdown = DurationBattleEnding * TickRate;
    dispatcher.broadcastMessage(message.opCode, message.data, null, message.sender);
}

Ending a match

When a player has reached 3 victories or all the players has been disconected the match ends, this can be done by returning null on any of the match fuctions, this behaviour can be seen on the matchLoop.

return gameState.endMatch ? null : { state: gameState };

Incrementing user trophies

The winner of the game gets a trophy when the match ends, to do this a storage read of a user is done and the variable is incremented by the desired amount and then a storage write is done after that.

let storageReadRequests: nkruntime.StorageReadRequest[] = [{
    collection: CollectionUser,
    key: KeyTrophies,
    userId: winner.presence.userId
}];

let result: nkruntime.StorageObject[] = nakama.storageRead(storageReadRequests);
var trophiesData: TrophiesData = { amount: 0 };
for (let storageObject of result)
{
    trophiesData = <TrophiesData>storageObject.value;
    break;
}

trophiesData.amount++;
let storageWriteRequests: nkruntime.StorageWriteRequest[] = [{
    collection: CollectionUser,
    key: KeyTrophies,
    userId: winner.presence.userId,
    value: trophiesData
}];

nakama.storageWrite(storageWriteRequests);

Credits

Programming: Alan Gaspar

Art: Monica Murillo

Music: FoxSynergy (8-BitNinja) and Spring Spring (Ninja Theme) (10 Fanfares)

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