use bincode::{deserialize, serialize};
use byteorder::{ByteOrder, LittleEndian};
use bytes::{Bytes, BytesMut};
use log::*;
use serde_derive::{Deserialize, Serialize};
use solana_metrics::datapoint_info;
use solana_sdk::{
hash::Hash,
message::Message,
packet::PACKET_DATA_SIZE,
pubkey::Pubkey,
signature::{Keypair, Signer},
system_instruction,
transaction::Transaction,
};
use std::{
io::{self, Error, ErrorKind},
net::{IpAddr, Ipv4Addr, SocketAddr, TcpStream},
sync::{mpsc::Sender, Arc, Mutex},
thread,
time::Duration,
};
use tokio::{
self,
net::TcpListener,
prelude::{Future, Read, Sink, Stream, Write},
};
use tokio_codec::{BytesCodec, Decoder};
#[macro_export]
macro_rules! socketaddr {
($ip:expr, $port:expr) => {
SocketAddr::from((Ipv4Addr::from($ip), $port))
};
($str:expr) => {{
let a: SocketAddr = $str.parse().unwrap();
a
}};
}
pub const TIME_SLICE: u64 = 60;
pub const REQUEST_CAP: u64 = solana_sdk::native_token::LAMPORTS_PER_SOL * 10_000_000;
pub const FAUCET_PORT: u16 = 9900;
pub const FAUCET_PORT_STR: &str = "9900";
#[derive(Serialize, Deserialize, Debug, Clone, Copy)]
pub enum FaucetRequest {
GetAirdrop {
lamports: u64,
to: Pubkey,
blockhash: Hash,
},
}
pub struct Faucet {
mint_keypair: Keypair,
ip_cache: Vec<IpAddr>,
pub time_slice: Duration,
request_cap: u64,
pub request_current: u64,
}
impl Faucet {
pub fn new(
mint_keypair: Keypair,
time_input: Option<u64>,
request_cap_input: Option<u64>,
) -> Faucet {
let time_slice = match time_input {
Some(time) => Duration::new(time, 0),
None => Duration::new(TIME_SLICE, 0),
};
let request_cap = match request_cap_input {
Some(cap) => cap,
None => REQUEST_CAP,
};
Faucet {
mint_keypair,
ip_cache: Vec::new(),
time_slice,
request_cap,
request_current: 0,
}
}
pub fn check_request_limit(&mut self, request_amount: u64) -> bool {
(self.request_current + request_amount) <= self.request_cap
}
pub fn clear_request_count(&mut self) {
self.request_current = 0;
}
pub fn add_ip_to_cache(&mut self, ip: IpAddr) {
self.ip_cache.push(ip);
}
pub fn clear_ip_cache(&mut self) {
self.ip_cache.clear();
}
pub fn build_airdrop_transaction(
&mut self,
req: FaucetRequest,
) -> Result<Transaction, io::Error> {
trace!("build_airdrop_transaction: {:?}", req);
match req {
FaucetRequest::GetAirdrop {
lamports,
to,
blockhash,
} => {
if self.check_request_limit(lamports) {
self.request_current += lamports;
datapoint_info!(
"faucet-airdrop",
("request_amount", lamports, i64),
("request_current", self.request_current, i64)
);
info!("Requesting airdrop of {} to {:?}", lamports, to);
let create_instruction =
system_instruction::transfer(&self.mint_keypair.pubkey(), &to, lamports);
let message = Message::new(&[create_instruction]);
Ok(Transaction::new(&[&self.mint_keypair], message, blockhash))
} else {
Err(Error::new(
ErrorKind::Other,
format!(
"token limit reached; req: {} current: {} cap: {}",
lamports, self.request_current, self.request_cap
),
))
}
}
}
}
pub fn process_faucet_request(&mut self, bytes: &BytesMut) -> Result<Bytes, io::Error> {
let req: FaucetRequest = deserialize(bytes).or_else(|err| {
Err(io::Error::new(
io::ErrorKind::Other,
format!("deserialize packet in faucet: {:?}", err),
))
})?;
info!("Airdrop transaction requested...{:?}", req);
let res = self.build_airdrop_transaction(req);
match res {
Ok(tx) => {
let response_vec = bincode::serialize(&tx).or_else(|err| {
Err(io::Error::new(
io::ErrorKind::Other,
format!("deserialize packet in faucet: {:?}", err),
))
})?;
let mut response_vec_with_length = vec![0; 2];
LittleEndian::write_u16(&mut response_vec_with_length, response_vec.len() as u16);
response_vec_with_length.extend_from_slice(&response_vec);
let response_bytes = Bytes::from(response_vec_with_length);
info!("Airdrop transaction granted");
Ok(response_bytes)
}
Err(err) => {
warn!("Airdrop transaction failed: {:?}", err);
Err(err)
}
}
}
}
impl Drop for Faucet {
fn drop(&mut self) {
solana_metrics::flush();
}
}
pub fn request_airdrop_transaction(
faucet_addr: &SocketAddr,
id: &Pubkey,
lamports: u64,
blockhash: Hash,
) -> Result<Transaction, Error> {
info!(
"request_airdrop_transaction: faucet_addr={} id={} lamports={} blockhash={}",
faucet_addr, id, lamports, blockhash
);
let mut stream = TcpStream::connect_timeout(faucet_addr, Duration::new(3, 0))?;
stream.set_read_timeout(Some(Duration::new(10, 0)))?;
let req = FaucetRequest::GetAirdrop {
lamports,
blockhash,
to: *id,
};
let req = serialize(&req).expect("serialize faucet request");
stream.write_all(&req)?;
let mut buffer = [0; 2];
stream.read_exact(&mut buffer).or_else(|err| {
info!(
"request_airdrop_transaction: buffer length read_exact error: {:?}",
err
);
Err(Error::new(ErrorKind::Other, "Airdrop failed"))
})?;
let transaction_length = LittleEndian::read_u16(&buffer) as usize;
if transaction_length >= PACKET_DATA_SIZE {
return Err(Error::new(
ErrorKind::Other,
format!(
"request_airdrop_transaction: invalid transaction_length from faucet: {}",
transaction_length
),
));
}
let mut buffer = Vec::new();
buffer.resize(transaction_length, 0);
stream.read_exact(&mut buffer).or_else(|err| {
info!(
"request_airdrop_transaction: buffer read_exact error: {:?}",
err
);
Err(Error::new(ErrorKind::Other, "Airdrop failed"))
})?;
let transaction: Transaction = deserialize(&buffer).or_else(|err| {
Err(Error::new(
ErrorKind::Other,
format!("request_airdrop_transaction deserialize failure: {:?}", err),
))
})?;
Ok(transaction)
}
pub fn run_local_faucet(
mint_keypair: Keypair,
sender: Sender<SocketAddr>,
request_cap_input: Option<u64>,
) {
thread::spawn(move || {
let faucet_addr = socketaddr!(0, 0);
let faucet = Arc::new(Mutex::new(Faucet::new(
mint_keypair,
None,
request_cap_input,
)));
run_faucet(faucet, faucet_addr, Some(sender));
});
}
pub fn run_faucet(
faucet: Arc<Mutex<Faucet>>,
faucet_addr: SocketAddr,
send_addr: Option<Sender<SocketAddr>>,
) {
let socket = TcpListener::bind(&faucet_addr).unwrap();
if let Some(send_addr) = send_addr {
send_addr.send(socket.local_addr().unwrap()).unwrap();
}
info!("Faucet started. Listening on: {}", faucet_addr);
let done = socket
.incoming()
.map_err(|e| debug!("failed to accept socket; error = {:?}", e))
.for_each(move |socket| {
let faucet2 = faucet.clone();
let framed = BytesCodec::new().framed(socket);
let (writer, reader) = framed.split();
let processor = reader.and_then(move |bytes| {
match faucet2.lock().unwrap().process_faucet_request(&bytes) {
Ok(response_bytes) => {
trace!("Airdrop response_bytes: {:?}", response_bytes.to_vec());
Ok(response_bytes)
}
Err(e) => {
info!("Error in request: {:?}", e);
Ok(Bytes::from(&b""[..]))
}
}
});
let server = writer
.send_all(processor.or_else(|err| {
Err(io::Error::new(
io::ErrorKind::Other,
format!("Faucet response: {:?}", err),
))
}))
.then(|_| Ok(()));
tokio::spawn(server)
});
tokio::run(done);
}
#[cfg(test)]
mod tests {
use super::*;
use bytes::BufMut;
use solana_sdk::system_instruction::SystemInstruction;
use std::time::Duration;
#[test]
fn test_check_request_limit() {
let keypair = Keypair::new();
let mut faucet = Faucet::new(keypair, None, Some(3));
assert!(faucet.check_request_limit(1));
faucet.request_current = 3;
assert!(!faucet.check_request_limit(1));
}
#[test]
fn test_clear_request_count() {
let keypair = Keypair::new();
let mut faucet = Faucet::new(keypair, None, None);
faucet.request_current = faucet.request_current + 256;
assert_eq!(faucet.request_current, 256);
faucet.clear_request_count();
assert_eq!(faucet.request_current, 0);
}
#[test]
fn test_add_ip_to_cache() {
let keypair = Keypair::new();
let mut faucet = Faucet::new(keypair, None, None);
let ip = "127.0.0.1".parse().expect("create IpAddr from string");
assert_eq!(faucet.ip_cache.len(), 0);
faucet.add_ip_to_cache(ip);
assert_eq!(faucet.ip_cache.len(), 1);
assert!(faucet.ip_cache.contains(&ip));
}
#[test]
fn test_clear_ip_cache() {
let keypair = Keypair::new();
let mut faucet = Faucet::new(keypair, None, None);
let ip = "127.0.0.1".parse().expect("create IpAddr from string");
assert_eq!(faucet.ip_cache.len(), 0);
faucet.add_ip_to_cache(ip);
assert_eq!(faucet.ip_cache.len(), 1);
faucet.clear_ip_cache();
assert_eq!(faucet.ip_cache.len(), 0);
assert!(faucet.ip_cache.is_empty());
}
#[test]
fn test_faucet_default_init() {
let keypair = Keypair::new();
let time_slice: Option<u64> = None;
let request_cap: Option<u64> = None;
let faucet = Faucet::new(keypair, time_slice, request_cap);
assert_eq!(faucet.time_slice, Duration::new(TIME_SLICE, 0));
assert_eq!(faucet.request_cap, REQUEST_CAP);
}
#[test]
fn test_faucet_build_airdrop_transaction() {
let to = Pubkey::new_rand();
let blockhash = Hash::default();
let request = FaucetRequest::GetAirdrop {
lamports: 2,
to,
blockhash,
};
let mint = Keypair::new();
let mint_pubkey = mint.pubkey();
let mut faucet = Faucet::new(mint, None, None);
let tx = faucet.build_airdrop_transaction(request).unwrap();
let message = tx.message();
assert_eq!(tx.signatures.len(), 1);
assert_eq!(
message.account_keys,
vec![mint_pubkey, to, Pubkey::default()]
);
assert_eq!(message.recent_blockhash, blockhash);
assert_eq!(message.instructions.len(), 1);
let instruction: SystemInstruction = deserialize(&message.instructions[0].data).unwrap();
assert_eq!(instruction, SystemInstruction::Transfer { lamports: 2 });
let mint = Keypair::new();
faucet = Faucet::new(mint, None, Some(1));
let tx = faucet.build_airdrop_transaction(request);
assert!(tx.is_err());
}
#[test]
fn test_process_faucet_request() {
let to = Pubkey::new_rand();
let blockhash = Hash::new(&to.as_ref());
let lamports = 50;
let req = FaucetRequest::GetAirdrop {
lamports,
blockhash,
to,
};
let req = serialize(&req).unwrap();
let mut bytes = BytesMut::with_capacity(req.len());
bytes.put(&req[..]);
let keypair = Keypair::new();
let expected_instruction = system_instruction::transfer(&keypair.pubkey(), &to, lamports);
let message = Message::new(&[expected_instruction]);
let expected_tx = Transaction::new(&[&keypair], message, blockhash);
let expected_bytes = serialize(&expected_tx).unwrap();
let mut expected_vec_with_length = vec![0; 2];
LittleEndian::write_u16(&mut expected_vec_with_length, expected_bytes.len() as u16);
expected_vec_with_length.extend_from_slice(&expected_bytes);
let mut faucet = Faucet::new(keypair, None, None);
let response = faucet.process_faucet_request(&bytes);
let response_vec = response.unwrap().to_vec();
assert_eq!(expected_vec_with_length, response_vec);
let mut bad_bytes = BytesMut::with_capacity(9);
bad_bytes.put("bad bytes");
assert!(faucet.process_faucet_request(&bad_bytes).is_err());
}
}