helios/client/src/node.rs

use std::collections::BTreeMap;
use std::sync::Arc;
use std::time::Duration;

use ethers::prelude::{Address, U256};
use ethers::types::{Transaction, TransactionReceipt, H256};
use eyre::{eyre, Result};

use common::errors::BlockNotFoundError;
use common::types::BlockTag;
use config::Config;
use consensus::rpc::nimbus_rpc::NimbusRpc;
use consensus::types::{ExecutionPayload, Header};
use consensus::ConsensusClient;
use execution::evm::Evm;
use execution::rpc::http_rpc::HttpRpc;
use execution::types::{CallOpts, ExecutionBlock};
use execution::ExecutionClient;

pub struct Node {
    consensus: ConsensusClient<NimbusRpc>,
    execution: ExecutionClient<HttpRpc>,
    config: Arc<Config>,
    payloads: BTreeMap<u64, ExecutionPayload>,
    finalized_payloads: BTreeMap<u64, ExecutionPayload>,
    history_size: usize,
}

impl Node {
    pub async fn new(config: Arc<Config>) -> Result<Self> {
        let consensus_rpc = &config.consensus_rpc;
        let checkpoint_hash = &config.checkpoint;
        let execution_rpc = &config.execution_rpc;

        let consensus =
            ConsensusClient::new(consensus_rpc, checkpoint_hash, config.clone()).await?;
        let execution = ExecutionClient::new(execution_rpc)?;

        let payloads = BTreeMap::new();
        let finalized_payloads = BTreeMap::new();

        Ok(Node {
            consensus,
            execution,
            config,
            payloads,
            finalized_payloads,
            history_size: 64,
        })
    }

    pub async fn sync(&mut self) -> Result<()> {
        self.consensus.sync().await?;
        self.update_payloads().await
    }

    pub async fn advance(&mut self) -> Result<()> {
        self.consensus.advance().await?;
        self.update_payloads().await
    }

    pub fn duration_until_next_update(&self) -> Duration {
        self.consensus
            .duration_until_next_update()
            .to_std()
            .unwrap()
    }

    async fn update_payloads(&mut self) -> Result<()> {
        let latest_header = self.consensus.get_header();
        let latest_payload = self
            .consensus
            .get_execution_payload(&Some(latest_header.slot))
            .await?;

        let finalized_header = self.consensus.get_finalized_header();
        let finalized_payload = self
            .consensus
            .get_execution_payload(&Some(finalized_header.slot))
            .await?;

        self.payloads
            .insert(latest_payload.block_number, latest_payload);
        self.payloads
            .insert(finalized_payload.block_number, finalized_payload.clone());
        self.finalized_payloads
            .insert(finalized_payload.block_number, finalized_payload);

        while self.payloads.len() > self.history_size {
            self.payloads.pop_first();
        }

        while self.finalized_payloads.len() > usize::max(self.history_size / 32, 1) {
            self.finalized_payloads.pop_first();
        }

        Ok(())
    }

    pub fn call(&self, opts: &CallOpts, block: &BlockTag) -> Result<Vec<u8>> {
        self.check_blocktag_age(block)?;

        let payload = self.get_payload(block)?;
        let mut evm = Evm::new(self.execution.clone(), payload.clone(), self.chain_id());
        evm.call(opts)
    }

    pub fn estimate_gas(&self, opts: &CallOpts) -> Result<u64> {
        self.check_head_age()?;

        let payload = self.get_payload(&BlockTag::Latest)?;
        let mut evm = Evm::new(self.execution.clone(), payload.clone(), self.chain_id());
        evm.estimate_gas(opts)
    }

    pub async fn get_balance(&self, address: &Address, block: &BlockTag) -> Result<U256> {
        self.check_blocktag_age(block)?;

        let payload = self.get_payload(block)?;
        let account = self.execution.get_account(&address, None, payload).await?;
        Ok(account.balance)
    }

    pub async fn get_nonce(&self, address: &Address, block: &BlockTag) -> Result<u64> {
        self.check_blocktag_age(block)?;

        let payload = self.get_payload(block)?;
        let account = self.execution.get_account(&address, None, payload).await?;
        Ok(account.nonce)
    }

    pub async fn get_code(&self, address: &Address, block: &BlockTag) -> Result<Vec<u8>> {
        self.check_blocktag_age(block)?;

        let payload = self.get_payload(block)?;
        let account = self.execution.get_account(&address, None, payload).await?;
        Ok(account.code)
    }

    pub async fn get_storage_at(&self, address: &Address, slot: H256) -> Result<U256> {
        self.check_head_age()?;

        let payload = self.get_payload(&BlockTag::Latest)?;
        let account = self
            .execution
            .get_account(address, Some(&[slot]), payload)
            .await?;

        let value = account.slots.get(&slot);
        match value {
            Some(value) => Ok(*value),
            None => Err(eyre!("slot not found")),
        }
    }

    pub async fn send_raw_transaction(&self, bytes: &Vec<u8>) -> Result<H256> {
        self.execution.send_raw_transaction(bytes).await
    }

    pub async fn get_transaction_receipt(
        &self,
        tx_hash: &H256,
    ) -> Result<Option<TransactionReceipt>> {
        self.execution
            .get_transaction_receipt(tx_hash, &self.payloads)
            .await
    }

    pub async fn get_transaction_by_hash(&self, tx_hash: &H256) -> Result<Option<Transaction>> {
        self.execution
            .get_transaction(tx_hash, &self.payloads)
            .await
    }

    pub fn get_gas_price(&self) -> Result<U256> {
        self.check_head_age()?;

        let payload = self.get_payload(&BlockTag::Latest)?;
        let base_fee = U256::from_little_endian(&payload.base_fee_per_gas.to_bytes_le());
        let tip = U256::from(10_u64.pow(9));
        Ok(base_fee + tip)
    }

    pub fn get_priority_fee(&self) -> Result<U256> {
        let tip = U256::from(10_u64.pow(9));
        Ok(tip)
    }

    pub fn get_block_number(&self) -> Result<u64> {
        self.check_head_age()?;

        let payload = self.get_payload(&BlockTag::Latest)?;
        Ok(payload.block_number)
    }

    pub async fn get_block_by_number(
        &self,
        block: &BlockTag,
        full_tx: bool,
    ) -> Result<Option<ExecutionBlock>> {
        self.check_blocktag_age(block)?;

        match self.get_payload(block) {
            Ok(payload) => self
                .execution
                .get_block(payload, full_tx)
                .await
                .map(|b| Some(b)),
            Err(_) => Ok(None),
        }
    }

    pub async fn get_block_by_hash(
        &self,
        hash: &Vec<u8>,
        full_tx: bool,
    ) -> Result<Option<ExecutionBlock>> {
        let payloads = self
            .payloads
            .iter()
            .filter(|entry| &entry.1.block_hash.to_vec() == hash)
            .collect::<Vec<(&u64, &ExecutionPayload)>>();

        match payloads.get(0) {
            Some(payload_entry) => self
                .execution
                .get_block(payload_entry.1, full_tx)
                .await
                .map(|b| Some(b)),
            None => Ok(None),
        }
    }

    pub fn chain_id(&self) -> u64 {
        self.config.chain.chain_id
    }

    pub fn get_header(&self) -> Result<Header> {
        self.check_head_age()?;
        Ok(self.consensus.get_header().clone())
    }

    pub fn get_last_checkpoint(&self) -> Option<Vec<u8>> {
        self.consensus.last_checkpoint.clone()
    }

    fn get_payload(&self, block: &BlockTag) -> Result<&ExecutionPayload> {
        match block {
            BlockTag::Latest => {
                let payload = self.payloads.last_key_value();
                Ok(payload.ok_or(BlockNotFoundError::new(BlockTag::Latest))?.1)
            }
            BlockTag::Finalized => {
                let payload = self.finalized_payloads.last_key_value();
                Ok(payload
                    .ok_or(BlockNotFoundError::new(BlockTag::Finalized))?
                    .1)
            }
            BlockTag::Number(num) => {
                let payload = self.payloads.get(num);
                payload.ok_or(BlockNotFoundError::new(BlockTag::Number(*num)).into())
            }
        }
    }

    fn check_head_age(&self) -> Result<()> {
        let synced_slot = self.consensus.get_header().slot;
        let expected_slot = self.consensus.expected_current_slot();
        let slot_delay = expected_slot - synced_slot;

        if slot_delay > 10 {
            return Err(eyre!("out of sync"));
        }

        Ok(())
    }

    fn check_blocktag_age(&self, block: &BlockTag) -> Result<()> {
        match block {
            BlockTag::Latest => self.check_head_age(),
            BlockTag::Finalized => Ok(()),
            BlockTag::Number(_) => Ok(()),
        }
    }
}