Svelto.ECS.Schema 0.1.0

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dotnet add package Svelto.ECS.Schema --version 0.1.0                
NuGet\Install-Package Svelto.ECS.Schema -Version 0.1.0                
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<PackageReference Include="Svelto.ECS.Schema" Version="0.1.0" />                
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paket add Svelto.ECS.Schema --version 0.1.0                
#r "nuget: Svelto.ECS.Schema, 0.1.0"                
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// Install Svelto.ECS.Schema as a Cake Addin
#addin nuget:?package=Svelto.ECS.Schema&version=0.1.0

// Install Svelto.ECS.Schema as a Cake Tool
#tool nuget:?package=Svelto.ECS.Schema&version=0.1.0                

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Svelto.ECS.Schema

Extension for Svelto.ECS, helps defining structure like database schema.

Motivation

Svelto.ECS is an awesome project, however I found understanding underlying entity structure can be pretty confusing to new users like myself. It has powerful tools like groups and filters, but lacks of wrapper to make it intutive. I thought it will be much easier to understand group with structured schema, and it is worth to make your code flexible, design change proof. That is the motivation I wrote this Svelto.ECS.Schema extension which is basically a user-friendly wrapper for groups and filters.

Concept

Think of a RDBMS schema, there is tables, records, columns, indexes and partitions. ECS is basically in-memory database but faster. In RDBMS, tables can hold records having specific combination of columns. In Svelto.ECS, groups can hold entities having specific combination of components. That is why I chose to take friendly terms from RDBMS and define schema of ECS.

Basic Usage

Install

Currently it is alpha stage, available on NuGet. While I don't recommend to use it on production, feel free to try it and please share me the experience! If you need help, you can either join my Discord Channel or ping @cathei from Svelto's Official Discord Channel.

Need help?

Defining Descriptor

Let's say you have basic understanding of general Entity-Component-System. Defining schema starts from defining EntityDescriptor, that is combination of components.

public class CharacterDescriptor : GenericEntityDescriptor<EGIDComponent, HealthComponent, PositionComponent> { }

It is not part of this extension, but it is important because it is basically definition of records that table can hold.

Defining Schema

Let's define simplest Schema.

public class GameSchema : IEntitySchema<GameSchema>
{
    public SchemaContext Context { get; set; }

    static Table<CharacterDescriptor> character = new Table<CharacterDescriptor>();
    public Group<CharacterDescriptor> Character => character.Group();

    static Table<ItemDescriptor> item = new Table<ItemDescriptor>();
    public Group<ItemDescriptor> Item => item.Group();
}

IEntitySchema<TSelf> represents a class that will hold all defined tables as member. Context property is requried by IEntitySchema<TSelf>.

Table<TDescriptor> represents underlying ExclusiveGroup. Tables should only accept entities using same descriptor, or else the index will break.

Note that tables are defined as static, and only Group<T> are exposed. This is pattern I recommend, so rest of your code can be kept clean and reslove all schema relatived code in schema class. Do not make methodes static, it is not safe to access to schema until it is added to EnginesRoot.

Defining Ranged Table

Sometimes you'll want many tables of same type, without defining many variables. Simiply pass the number of group you want to be created, and there are multiple separated tables!

public class AnotherSchema : IEntitySchema<AnotherSchema>
{
    public SchemaContext Context { get; set; }

    public enum ItemType { Potion, Weapon, Armor, MAX };

    public const int MaxPlayerCount = 10;

    static Table<ItemDescriptor> items = new Table<ItemDescriptor>((int)ItemType.MAX);
    public Group<ItemDescriptor> Items(ItemType type) => items.Group((int)type);

    static Table<PlayerDescriptor> players = new Table<PlayerDescriptor>(MaxPlayerCount);
    public Group<PlayerDescriptor> Player(int playerId) => players.Group(playerId);

    public Groups<PlayerDescriptor> AllPlayers => players.Groups();
}

Above example shows use case of ranged tables with number or enum.

Note that we also exposes AnotherSchema.AllPlayers which represents all player groups. Groups<T> is actually a builder for FasterList<ExclusiveGroupStruct>. Call Groups<T>.Build() and cache the result. Then you can pass the list to EntitiesDB.QueryEntities.

// you probably wanna cache this
FasterList<ExclusiveGroupStruct> allPlayerGroups = schema.AllPlayers.Build();

foreach (var (...) in entitiesDB.QueryEntities<...>(allPlayerGroups)) { }

Defining Partition

On the other hand, you will want to group some related tables, and reuse it. We use Partition<TShard> for it. First, define a shard, which is logical group of tables.

public struct PlayerShard : IEntityShard
{
    public ShardOffset Offset { get; set; }

    public enum ItemType { Potion, Weapon, Armor, MAX };

    static Table<CharacterDescriptor> aliveCharacter = new Table<CharacterDescriptor>();
    public Group<CharacterDescriptor> AliveCharacter => aliveCharacter.At(Offset).Group();

    static Table<CharacterDescriptor> deadCharacter = new Table<CharacterDescriptor>();
    public Group<CharacterDescriptor> DeadCharacter => deadCharacter.At(Offset).Group();

    static Table<ItemDescriptor> items = new Table<ItemDescriptor>((int)ItemType.MAX);
    public Group<ItemDescriptor> Item(ItemType type) => items.At(Offset).Group((int)type);
}

Looks similar to defining schema, but little different. First, PlayerShard is struct. Second, there is Offset property which defined in IEntityShard, and they are passed in properties by .At(Offset) before get the underlying group.

Reason of this is PlayerShard can be reused but tables will be static. So we need to pass a Offset information to get the correct group when accessed from different partition.

Now we have Shard, we can define actual partition with Partition<TShard> in the schema.

public class MyGameSchema : IEntitySchema<MyGameSchema>
{
    public const int MaxPlayerCount = 10;

    public SchemaContext Context { get; set; }

    static Partition<PlayerShard> ai = new Partition<PlayerShard>();
    public PlayerShard AI => ai.Shard();

    static Partition<PlayerShard> players = new Partition<PlayerShard>(MaxPlayerCount);
    public PlayerShard Player(int playerId) => players.Shard(playerId);

    public Groups<CharacterDescriptor> AllAliveCharacters =>
        AI.AliveCharacter + players.Shards().Each(x => x.AliveCharacter);
}

Nice. We defined a group for AI, and 10 players. Just like how we expose group instead of table, we'll expose shard insted of partition. If you want to access group for player 5's alive characters, use MyGameSchema.Player(5).AliveCharacter. Also we added shortcut groups for all alive characters.

Applying Schema

Before we can use schema, we need to call EnginesRoot.AddSchema<T>(). When you initializing EnginesRoot, do this before any entitiy submission.

MyGameSchema schema = enginesRoot.AddSchema<MyGameSchema>();

Now it's time to fill up your tables with records.

public class CompositionRoot
{
    private uint eidCounter = 0;

    public CompositionRoot()
    {
        var submissionScheduler = new SimpleEntitiesSubmissionScheduler();
        var enginesRoot = new EnginesRoot(submissionScheduler);

        var entityFactory = enginesRoot.GenerateEntityFactory();
        var schema = enginesRoot.AddSchema<MyGameSchema>();

        for (int i = 0; i < 10; ++i)
            AddCharacter(entityFactory, schema.AI.AliveCharacter);

        for (int i = 0; i < 10; ++i)
            AddCharacter(entityFactory, schema.Player(0).DeadCharacter);

        submissionScheduler.SubmitEntities();
    }

    private void AddCharacter(IEntityFactory entityFactory, Group<CharacterDescriptor> group)
    {
        var builder = entityFactory.BuildEntity(eidCounter++, group);

        builder.Init(new HealthComponent(1000));
        builder.Init(new PositionComponent(0, 0));
    }
}

Above we have example to put 10 characters to alive, AI controlled character group, and put another 10 characters to dead, player 0 controlled character group. You don't have to specify descriptor when call BuildEntity, because group is already implying descriptor type.

Inject schema to your engines. Now you can query this from your desired engine.

// you probably wanna cache this
FastList<ExclusiveGroupStruct> allAliveCharactersGroup = schema.AllAliveCharacters.Build();

foreach (var ((healths, positions, count), group) in entitiesDB.QueryEntities<HealthComponent, PositionComponent>(allAliveCharactersGroup))
{
    for (int i = 0; i < count; ++i)
    {
        healths[i].current -= 100;
    }
}

vs. Doofuses example

GroupCompound is good enough for simple, static groups. But not all the groups in game is simple or static. Most of them are not, actually. Let's look at the Doofuses example of Svelto.ECS.MiniExamples. They have groups like this.

static class GameGroups
{
    public class DOOFUSES : GroupTag<DOOFUSES> { }
    public class FOOD : GroupTag<FOOD> { }
    
    public class RED : GroupTag<RED> { }
    public class BLUE : GroupTag<BLUE> { }
    
    public class EATING : GroupTag<EATING> { }
    public class NOTEATING : GroupTag<NOTEATING> { }

    public class RED_DOOFUSES_EATING : GroupCompound<DOOFUSES, RED, EATING> { };
    public class RED_DOOFUSES_NOT_EATING :  GroupCompound<DOOFUSES, RED, NOTEATING> { };
    public class RED_FOOD_EATEN : GroupCompound<FOOD, RED, EATING> { };
    public class RED_FOOD_NOT_EATEN : GroupCompound<FOOD, RED, NOTEATING> { };
    
    public class BLUE_DOOFUSES_EATING : GroupCompound<DOOFUSES, BLUE, EATING> { };
    public class BLUE_DOOFUSES_NOT_EATING :  GroupCompound<DOOFUSES, BLUE, NOTEATING> { };
    public class BLUE_FOOD_EATEN : GroupCompound<FOOD, BLUE, EATING> { };
    public class BLUE_FOOD_NOT_EATEN : GroupCompound<FOOD, BLUE, NOTEATING> { };

    public class DOOFUSES_EATING : GroupCompound<DOOFUSES, EATING> { };
}

There is entity type of Doofuses and Food, team of Red and Blue, state of Eating and NonEating. And groups are made with their combinations. I think it will be easy if you get used to it, but little confusing to understand structure at the first.

Real problem is it is not really flexible nor extendible. What if Yellow team is needed? What if state of Flying and Ground is needed? We'll have to define all the combinations we need. Game design will change over time, and I think it is not managable through GroupCompound at some point.

With Schema extension this would be converted to below.

public struct StateShard : IEntityShard
{
    public ShardOffset Offset { get; set; }

    static Table<DoofusEntityDescriptor> doofus = new Table<DoofusEntityDescriptor>();
    public Group<DoofusEntityDescriptor> Doofus => doofus.At(Offset).Group();

    static Table<FoodEntityDescriptor> food = new Table<FoodEntityDescriptor>();
    public Group<FoodEntityDescriptor> Food => food.At(Offset).Group();
}

public struct TeamShard : IEntityShard
{
    public ShardOffset Offset { get; set; }

    static Partition<StateShard> eating = new Partition<StateShard>();
    public StateShard Eating => eating.At(Offset).Shard();

    static Partition<StateShard> nonEating = new Partition<StateShard>();
    public StateShard NonEating => nonEating.At(Offset).Shard();
}

public enum TeamColor { Red, Blue, MAX }

public class GameSchema : IEntitySchema<GameSchema>
{
    public SchemaContext Context { get; set; }

    static Partition<TeamShard> team = new Partition<TeamShard>((int)TeamColor.MAX);
    public TeamShard Team(TeamColor color) => team.Shard((int)color);

    public Groups<DoofusEntityDescriptor> EatingDoofuses => team.Shards().Each(x => x.Eating.Doofus);
}

More code, but you'll thank to some complexity when you have to deal with big design changes!

When using it, code GameGroups.RED_DOOFUSES_EATING.Groups would be equvalent to GameSchema.Team(TeamColor.Red).Eating.Doofus.

Defining Indexes

Index is wrapper of filters system, but works like indexes in RDBMS. Filters are used to have subset from a group. Indexes are to collect entities by specific key, from a partition or entire schema. Let's take a look. You have to define Key first.

public readonly struct Controller : IEntityIndexKey
{
    public readonly int playerId;

    public int Key => playerId;

    public Controller(int playerId)
    {
        this.playerId = playerId;
    }
}

Keys are structs inheriting IEntityIndexKey. You can have more members in it, but you need to provide which member or combination will be Key. If the type is not int, consider using GetHashCode(). Also key are not meant to be mutable so I added readonly constraint but it is your choice.

Then, you add Indexed<TKey> to your descriptor.

public class CharacterDescriptor<HealthComponent, PositionComponent, Indexed<Controller>> { }

Indexed is special component to make sure that indexes are up-to-date. It has Controller struct as member Content, but you cannot change the value unless you use Indexed<TKey>.Update(SchemaContext, TKey). SchemaContext is accessable with IEntitySchema<T>.Context and represents current state of entity, like indexing.

Before look into SchemaContext, Let's add Index<TKey> to our schema.

public class IndexedSchema : IEntitySchema<IndexedSchema>
{
    static Table<CharacterDescriptor> flyingCharacter = new Table<CharacterDescriptor>();
    public Group<CharacterDescriptor> FlyingCharacter => flyingCharacter.Group();

    static Table<CharacterDescriptor> groundCharacter = new Table<CharacterDescriptor>();
    public Group<CharacterDescriptor> GroundCharacter => flyingCharacter.Group();

    static Index<Controller> charactersByController = new Index<Controller>();
    public IndexQuery CharactersByController(int playerId) => charactersByController.Query(playerId);
}

Index<TKey> will index any Indexed<TKey> component in any tables with same partition. Any child partition will be indexed as well. If Index<TKey> is defined in root schema, any table with Indexed<TKey> will be indexed. In this example both FlyingCharacter and GroundCharacter group will be indexed and returned when queried. If you want to index specific groups only, define a partition.

Same manner as we expose a group for a table, we'll expose IndexQuery for a index. IndexQuery is query for a specific key, like 'player id 0'.

Though there is no constraint yet, it is not recommended to share Indexed<TKey> across other descriptors.

Querying Indexes

Now, finally you can iterate over entities with IndexQuery. You don't have to include Indexed<TKey> in the query. You can query any type of component within the descriptor, because as long as you keep a group with single descriptor you can iterate with same filter.

Just like when you query with EntitiesDB, you query with SchemaContext.

foreach (var ((health, position, indices), group) in schema.Context.QueryEntities<HealthComponent, PositionComponent>(schema.CharactersByController(3)))
{
    for (int i = 0; i < indices.count(); ++i)
    {
        health[indices[i]].current += 10;
    }
}

Note that you have to use double indexing like health[indices[i]]. DO NOT update Indexed component while iterating through index query with it. It is undefined behaviour.

Naming Convention

Below is naming convention suggestions to make schema more readable. Optionally you could apply preceding _ for private static members.

For Tables and Partitions

  • Use singularNoun for singluar table.
  • Use pluralNouns for ranged table.
  • Use SingularNoun for Group<T>.
  • Use PluralNouns for Groups<T>.

For Partitions

  • Use adjective or singluarNoun for singular partition. e.g. flying
  • Use adjective or pluralNouns for ranged partition.
  • Use Adjective or SingularNoun for result of Shard(). e.g. Flying, so you can access like Flying.Monster
  • Use Adjective or PluralNouns for result of Shards().

For Indexes

  • Use TableNameKeyName for IEntityIndexKey. e.g. ItemHolder
  • Use tableNamesByKeyName for Index<T>. e.g. itemsByHodler
  • Use TableNameByKeyName for IndexQuery. e.g. ItemsByHolder
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