# Match-3 with ML-Agents ## Overview One of the main feedback we get is to illustrate more real game examples using ML-Agents. We are excited to provide an example implementation of Match-3 using ML-Agents and additional utilities to integrate ML-Agents with Match-3 games. Our aim is to enable Match-3 teams to leverage ML-Agents to create player agents to learn and play different Match-3 levels. This implementation is intended as a starting point and guide for teams to get started (as there are many nuances with Match-3 for training ML-Agents) and for us to iterate both on the C#, hyperparameters, and trainers to improve ML-Agents for Match-3. This implementation includes: * C# implementation catered toward a Match-3 setup including concepts around encoding for moves based on [Human Like Playtesting with Deep Learning](https://www.researchgate.net/publication/328307928_Human-Like_Playtesting_with_Deep_Learning) * An example Match-3 scene with ML-Agents implemented (located under /Project/Assets/ML-Agents/Examples/Match3). More information, on Match-3 example [here](https://github.com/Unity-Technologies/ml-agents/tree/release_16_docs/docs/docs/Learning-Environment-Examples.md#match-3). ### Feedback If you are a Match-3 developer and are trying to leverage ML-Agents for this scenario, [we want to hear from you](https://forms.gle/TBsB9jc8WshgzViU9). Additionally, we are also looking for interested Match-3 teams to speak with us for 45 minutes. If you are interested, please indicate that in the [form](https://forms.gle/TBsB9jc8WshgzViU9). If selected, we will provide gift cards as a token of appreciation. ### Interested in more game templates? Do you have a type of game you are interested for ML-Agents? If so, please post a [forum issue](https://forum.unity.com/forums/ml-agents.453/) with [GAME TEMPLATE] in the title. ## Getting started The C# code for Match-3 exists inside of the extensions package (com.unity.ml-agents.extensions). A good first step would be to familiarize with the extensions package by reading the document [here](com.unity.ml-agents.extensions.md). The second step would be to take a look at how we have implemented the C# code in the example Match-3 scene (located under /Project/Assets/ML-Agents/Examples/match3). Once you have some familiarity, then the next step would be to implement the C# code for Match-3 from the extensions package. Additionally, see below for additional technical specifications on the C# code for Match-3. Please note the Match-3 game isn't human playable as implemented and can be only played via training. ## Technical specifications for Match-3 with ML-Agents ### AbstractBoard class The `AbstractBoard` is the bridge between ML-Agents and your game. It allows ML-Agents to * ask your game what the "color" of a cell is * ask whether the cell is a "special" piece type or not * ask your game whether a move is allowed * request that your game make a move These are handled by implementing the `GetCellType()`, `IsMoveValid()`, and `MakeMove()` abstract methods. The AbstractBoard also tracks the number of rows, columns, and potential piece types that the board can have. ##### `public abstract int GetCellType(int row, int col)` Returns the "color" of piece at the given row and column. This should be between 0 and NumCellTypes-1 (inclusive). The actual order of the values doesn't matter. ##### `public abstract int GetSpecialType(int row, int col)` Returns the special type of the piece at the given row and column. This should be between 0 and NumSpecialTypes (inclusive). The actual order of the values doesn't matter. ##### `public abstract bool IsMoveValid(Move m)` Check whether the particular `Move` is valid for the game. The actual results will depend on the rules of the game, but we provide the `SimpleIsMoveValid()` method that handles basic match3 rules with no special or immovable pieces. ##### `public abstract bool MakeMove(Move m)` Instruct the game to make the given move. Returns true if the move was made. Note that during training, a move that was marked as invalid may occasionally still be requested. If this happens, it is safe to do nothing and request another move. ### Move struct The Move struct encapsulates a swap of two adjacent cells. You can get the number of potential moves for a board of a given size with. `Move.NumPotentialMoves(NumRows, NumColumns)`. There are two helper functions to create a new `Move`: * `public static Move FromMoveIndex(int moveIndex, int maxRows, int maxCols)` can be used to iterate over all potential moves for the board by looping from 0 to `Move.NumPotentialMoves()` * `public static Move FromPositionAndDirection(int row, int col, Direction dir, int maxRows, int maxCols)` creates a `Move` from a row, column, and direction (and board size). #### `Match3Sensor` and `Match3SensorComponent` classes The `Match3Sensor` generates observations about the state using the `AbstractBoard` interface. You can choose whether to use vector or "visual" observations; in theory, visual observations should perform better because they are 2-dimensional like the board, but we need to experiment more on this. A `Match3SensorComponent` generates a `Match3Sensor` at runtime, and should be added to the same GameObject as your `Agent` implementation. You do not need to write any additional code to use them. #### `Match3Actuator` and `Match3ActuatorComponent` classes The `Match3Actuator` converts actions from training or inference into a `Move` that is sent to` AbstractBoard.MakeMove()` It also checks `AbstractBoard.IsMoveValid` for each potential move and uses this to set the action mask for Agent. A `Match3ActuatorComponent` generates a `Match3Actuator` at runtime, and should be added to the same GameObject as your `Agent` implementation. You do not need to write any additional code to use them. ### Setting up Match-3 simulation * Implement the `AbstractBoard` methods to integrate with your game. * Give the `Agent` rewards when it does what you want it to (match multiple pieces in a row, clears pieces of a certain type, etc). * Add the `Agent`, `AbstractBoard` implementation, `Match3SensorComponent`, and `Match3ActuatorComponent` to the same `GameObject`. * Call `Agent.RequestDecision()` when you're ready for the `Agent` to make a move on the next `Academy` step. During the next `Academy` step, the `MakeMove()` method on the board will be called.