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matrix-rust-sdk/design.md

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Matrix Rust SDK

Design and Layout

Async Client

The highest level structure that ties the other pieces of functionality together. The client is responsible for the Request/Response cycle. It can be thought of as a thin layer atop the BaseClient passing requests along for the BaseClient to handle. A user should be able to write their own AsyncClient using the BaseClient. It knows how to

  • login
  • send messages
  • encryption ...
  • sync client state with the server
  • make raw Http requests

Base Client/Client State Machine

In addition to Http, the AsyncClient passes along methods from the BaseClient that deal with Rooms and RoomMembers. This allows the client to keep track of more complicated information that needs to be calculated in some way.

  • human-readable room names
  • power level?
  • ignored list?
  • push rulesset?
  • more?

Crypto State Machine

Given a Matrix response the crypto machine will update its own internal state, along with encryption information. BaseClient and the crypto machine together keep track of when to encrypt. It knows when encryption needs to happen based on signals from the BaseClient. The crypto state machine is given responses that relate to encryption and can create encrypted request bodies for encryption-related requests. Basically it tells the BaseClient to send to-device messages out, and the BaseClient is responsible for notifying the crypto state machine when it sent the message so crypto can update state.

Client State/Room and RoomMember

The BaseClient is responsible for keeping state in sync through the IncomingResponses of AsyncClient or querying the StateStore. By processing and then delegating incoming RoomEvents, StateEvents, PresenceEvent, IncomingAccountData and EphemeralEvents to the correct Room in the base clients HashMap<RoomId, Room> or further to Room's RoomMember via the members HashMap<UserId, RoomMember>. The BaseClient is also responsible for emitting the incoming events to the EventEmitter trait.

/// A Matrix room.
pub struct Room {
    /// The unique id of the room.
    pub room_id: RoomId,
    /// The name of the room, clients use this to represent a room.
    pub room_name: RoomName,
    /// The mxid of our own user.
    pub own_user_id: UserId,
    /// The mxid of the room creator.
    pub creator: Option<UserId>,
    /// The map of room members.
    pub members: HashMap<UserId, RoomMember>,
    /// A list of users that are currently typing.
    pub typing_users: Vec<UserId>,
    /// The power level requirements for specific actions in this room
    pub power_levels: Option<PowerLevels>,
    // TODO when encryption events are handled we store algorithm used and rotation time.
    /// A flag indicating if the room is encrypted.
    pub encrypted: bool,
    /// Number of unread notifications with highlight flag set.
    pub unread_highlight: Option<UInt>,
    /// Number of unread notifications.
    pub unread_notifications: Option<UInt>,
}

pub struct RoomMember {
    /// The unique mxid of the user.
    pub user_id: UserId,
    /// The human readable name of the user.
    pub display_name: Option<String>,
    /// The matrix url of the users avatar.
    pub avatar_url: Option<String>,
    /// The time, in ms, since the user interacted with the server.
    pub last_active_ago: Option<UInt>,
    /// If the user should be considered active.
    pub currently_active: Option<bool>,
    /// The unique id of the room.
    pub room_id: Option<String>,
    /// If the member is typing.
    pub typing: Option<bool>,
    /// The presence of the user, if found.
    pub presence: Option<PresenceState>,
    /// The presence status message, if found.
    pub status_msg: Option<String>,
    /// The users power level.
    pub power_level: Option<Int>,
    /// The normalized power level of this `RoomMember` (0-100).
    pub power_level_norm: Option<Int>,
    /// The `MembershipState` of this `RoomMember`.
    pub membership: MembershipState,
    /// The human readable name of this room member.
    pub name: String,
    /// The events that created the state of this room member.
    pub events: Vec<Event>,
    /// The `PresenceEvent`s connected to this user.
    pub presence_events: Vec<PresenceEvent>,
}

State Store

The BaseClient also has access to a dyn StateStore this is an abstraction around a "database" to keep the client state without requesting a full sync from the server on startup. A default implementation that serializes/deserializes JSON to files in a specified directory can be used. The user can also implement StateStore to fit any storage solution they choose. The base client handles the storage automatically. There "may be/are TODO" ways for the user to interact directly. The room event handling methods signal if the state was modified; if so, we check if some room state file needs to be overwritten.

  • open
  • load client/rooms
  • store client/room
  • update ??

The state store will restore our client state in the BaseClient and client authors can just get the latest state that they want to present from the client object. No need to ask the state store for it, this may change if custom setups request this. StateStore's main purpose is to provide load/store functionality and, internally to the crate, update the BaseClient.

Event Emitter

The consumer of this crate can implement the EventEmitter trait for full control over how incoming events are handled by their client. If that isn't enough, it is possible to receive every incoming response with the AsyncClient::sync_forever callback.

  • list the methods for EventEmitter?