Handle Reply with wait() and wake()

Now, let's apply understanding of the exec::wait()/exec::wake() functions to enhance the program introduced in the previous lesson:

The user will now receive a single reply at the end of the entire process, instead of two separate messages.

Proxy Program

Since the Target program remains unchanged, let's take a closer look at the changes in the Proxy program:

type SentMessageId = MessageId;
type OriginalMessageId = MessageId;

struct Session {
    target_program_id: ActorId,
    msg_ids: (SentMessageId, OriginalMessageId),
    session_status: SessionStatus,
}

New fields have been introduced:

• msg_ids — a tuple consisting of two elements: SentMessageId and OriginalMessageId;
  • SentMessageId is the identifier of the message sent to the target program's address.
  • OriginalMessageId is the identifier of the message sent to the proxy program by user (required for using the wake() function).
• session_status - the session status (required to track the stages of session activity).

enum SessionStatus {
    Waiting,
    MessageSent,
    ReplyReceived(Event),
}

• Waiting — the session is in a waiting state.
• MessageSent - the intermediate session state in which the message was sent to the target program, but the response has not yet been received.
• ReplyReceived(String) - the session state when the reply message has been received.

With these new fields in the program structure, initialization is as follows:

#[no_mangle]
extern "C" fn init() {
    let target_program_id = msg::load().expect("Unable to decode Init");
    unsafe {
        SESSION = Some(Session {
            target_program_id,
            msg_ids: (MessageId::zero(), MessageId::zero()),
            session_status: SessionStatus::Waiting,
        });
    }
}

To gain a comprehensive understanding of the process, let's incorporate debugging into the program.

#[no_mangle]
extern "C" fn handle() {
    debug!("!!!! HANDLE !!!!");
    debug!("Message ID: {:?}", msg::id());
    let action: Action = msg::load().expect("Unable to decode `Action`");
    debug!("Message payload: {:?}", action);
    let session = unsafe { SESSION.as_mut().expect("The session is not initialized") };

    // match session_status
    match &session.session_status {
        SessionStatus::Waiting => {
            debug!("HANDLE: SessionStatus::Waiting");
            let msg_id = msg::send(session.target_program_id, action, 0)
                .expect("Error in sending a message");
            debug!("HANDLE: SessionStatus::Sent");
            session.session_status = SessionStatus::MessageSent;
            session.msg_ids = (msg_id, msg::id());
            debug!("HANDLE: WAIT");
            exec::wait();
        }
        SessionStatus::MessageSent => {
            debug!("HANDLE: SessionStatus::MessageSent");
            msg::reply(Event::MessageAlreadySent, 0).expect("Error in sending a reply");
        }
        SessionStatus::ReplyReceived(reply_message) => {
            debug!("HANDLE: SessionStatus::ReplyReceived({:?})", reply_message);
            msg::reply(reply_message, 0).expect("Error in sending a reply");
            session.session_status = SessionStatus::Waiting;
        }
    }
    debug!("HANDLE: END");
}

Initially, the session is in SessionStatus::Waiting state. Upon a match, the code switches to the proxy option. The program sends a message, sets the session status to SessionStatus::MessageSent, and records the identifiers of the current message from user being processed and message sent to target program. Then, exec::wait() is called, pausing message processing and adding the current message to the waiting list until exec::wake(message_id) is called or the gas runs out. The ID of the waking message is crucial, hence msg::id() is stored in session.msg_ids.

Moving to the handle_reply() function:

#[no_mangle]
extern "C" fn handle_reply() {
    debug!("HANDLE_REPLY");
    let reply_to = msg::reply_to().expect("Failed to query reply_to data");
    let session = unsafe { SESSION.as_mut().expect("The session is not initialized") };

    if reply_to == session.msg_ids.0 && session.session_status == SessionStatus::MessageSent {
        let reply_message: Event = msg::load().expect("Unable to decode `Event`");
        debug!("HANDLE_REPLY: SessionStatus::ReplyReceived {:?}", reply_message);
        session.session_status = SessionStatus::ReplyReceived(reply_message);
        let original_message_id = session.msg_ids.1;
        debug!("HANDLE: WAKE");
        exec::wake(original_message_id).expect("Failed to wake message");
    }
}

The condition if reply_to == session.msg_ids.0 && session.session_status == SessionStatus::MessageSent ensures the expected message has arrived at the right moment, i.e., when the session is in the correct status. The status is then set to SessionStatus::ReplyReceived(reply_message), and the reply message is saved. The ID of the original message is retrieved, and the exec::wake() function is called. This function takes the message from the waiting list, and the suspended message resumes processing in the handle() function.

Important note: When exec::wake() is called, and the message returns to the handle() entry point, processing starts from the beginning. The program enters the match again:

// ...
match &session.session_status {
    // ...
    SessionStatus::ReplyReceived(reply_message) => {
        debug!("HANDLE: SessionStatus::ReplyReceived({:?})", reply_message);
        msg::reply(reply_message, 0).expect("Error in sending a reply");
        session.session_status = SessionStatus::Waiting;
    }
    // ...

However, this time, it proceeds to the third option according to the session state, sends a reply from the Target program to the user, and sets the status to SessionStatus::Waiting.

Let's review this process as a whole: