use bft_crdt_derive::add_crdt_fields;

use bft_json_crdt::{
    json_crdt::{BaseCrdt, CrdtNode, IntoCrdtNode},
    keypair::{make_keypair, Ed25519KeyPair},
    list_crdt::ListCrdt,
};

use serde::{Deserialize, Serialize};
use serde_json::{json, Value};
use websockets::WebSocket;

#[add_crdt_fields]
#[derive(Clone, CrdtNode, Serialize, Deserialize)]
pub(crate) struct ListExample {
    pub(crate) list: ListCrdt<Transaction>, // switch to Transaction as soon as char is working
}

/// A fake Transaction struct we can use as a simulated payload
#[add_crdt_fields]
#[derive(Clone, CrdtNode, Serialize, Deserialize)]
pub(crate) struct Transaction {
    from: String,
    to: String,
    amount: f64,
}

pub(crate) fn new() -> (BaseCrdt<ListExample>, Ed25519KeyPair) {
    let keys = make_keypair();
    let bft_crdt = BaseCrdt::<ListExample>::new(&keys);
    (bft_crdt, keys)
}

pub(crate) async fn send(
    count: u32,
    bft_crdt: &mut BaseCrdt<ListExample>,
    ws: &mut WebSocket,
    keys: &Ed25519KeyPair,
) -> Result<(), websockets::WebSocketError> {
    // generate a placeholder transaction
    let transaction = generate_transaction(count);

    // next job is to keep adding to this guy
    let signed_op = bft_crdt
        .doc
        .list
        .insert_idx(0, transaction.clone())
        .sign(&keys);
    println!("SignedOp being sent is: {:?}", signed_op);

    println!("Sending: {:?}", signed_op);
    Ok(ws
        .send_text(serde_json::to_string(&signed_op).unwrap())
        .await?)
}

fn generate_transaction(count: u32) -> Value {
    json!({
        "from": "Alice",
        "to": "Bob",
        "amount": count
    })
}