use std::{cmp, mem};
use std::collections::{HashSet, HashMap, hash_map};
use std::sync::{Arc, RwLock};
-use std::net::{IpAddr, Ipv4Addr, Ipv6Addr, SocketAddr};
+use std::net::{IpAddr, Ipv4Addr, Ipv6Addr, SocketAddr, SocketAddrV4, SocketAddrV6};
use std::time::{Duration, Instant};
use std::io::{BufRead, BufReader};
use crate::bgp_client::BGPClient;
+pub const SECS_PER_SCAN_RESULTS: u64 = 15;
+const MAX_CONNS_PER_SEC_PER_STATUS: u64 = 30;
+
#[derive(Clone, Copy, Hash, PartialEq, Eq)]
pub enum AddressState {
Untested,
#[derive(Hash, PartialEq, Eq)]
pub enum U64Setting {
- ConnsPerSec,
RunTimeout,
WasGoodTimeout,
RescanInterval(AddressState),
last_good: Instant, // Ignored unless state is Good or WasGood
last_services: u64,
state: AddressState,
+ queued: bool,
+}
+
+/// Essentially SocketAddr but without a traffic class or scope
+#[derive(Clone, PartialEq, Eq, Hash)]
+enum SockAddr {
+ V4(SocketAddrV4),
+ V6((Ipv6Addr, u16)),
+}
+impl From<SocketAddr> for SockAddr {
+ fn from(addr: SocketAddr) -> SockAddr {
+ match addr {
+ SocketAddr::V4(sa) => SockAddr::V4(sa),
+ SocketAddr::V6(sa) => SockAddr::V6((sa.ip().clone(), sa.port())),
+ }
+ }
+}
+impl Into<SocketAddr> for &SockAddr {
+ fn into(self) -> SocketAddr {
+ match self {
+ &SockAddr::V4(sa) => SocketAddr::V4(sa),
+ &SockAddr::V6(sa) => SocketAddr::V6(SocketAddrV6::new(sa.0, sa.1, 0, 0))
+ }
+ }
+}
+impl ToString for SockAddr {
+ fn to_string(&self) -> String {
+ let sa: SocketAddr = self.into();
+ sa.to_string()
+ }
+}
+impl SockAddr {
+ pub fn port(&self) -> u16 {
+ match *self {
+ SockAddr::V4(sa) => sa.port(),
+ SockAddr::V6((_, port)) => port,
+ }
+ }
+ pub fn ip(&self) -> IpAddr {
+ match *self {
+ SockAddr::V4(sa) => IpAddr::V4(sa.ip().clone()),
+ SockAddr::V6((ip, _)) => IpAddr::V6(ip),
+ }
+ }
}
struct Nodes {
- good_node_services: Vec<HashSet<SocketAddr>>,
- nodes_to_state: HashMap<SocketAddr, Node>,
- state_next_scan: Vec<Vec<(Instant, SocketAddr)>>,
+ good_node_services: [HashSet<SockAddr>; 64],
+ nodes_to_state: HashMap<SockAddr, Node>,
+ state_next_scan: Vec<Vec<(Instant, SockAddr)>>,
}
struct NodesMutRef<'a> {
- good_node_services: &'a mut Vec<HashSet<SocketAddr>>,
- nodes_to_state: &'a mut HashMap<SocketAddr, Node>,
- state_next_scan: &'a mut Vec<Vec<(Instant, SocketAddr)>>,
-
+ good_node_services: &'a mut [HashSet<SockAddr>; 64],
+ nodes_to_state: &'a mut HashMap<SockAddr, Node>,
+ state_next_scan: &'a mut Vec<Vec<(Instant, SockAddr)>>,
}
+
impl Nodes {
fn borrow_mut<'a>(&'a mut self) -> NodesMutRef<'a> {
NodesMutRef {
} }
}
let mut u64s = HashMap::with_capacity(AddressState::get_count() as usize + 4);
- u64s.insert(U64Setting::ConnsPerSec, try_read!(l, u64));
u64s.insert(U64Setting::RunTimeout, try_read!(l, u64));
u64s.insert(U64Setting::WasGoodTimeout, try_read!(l, u64));
u64s.insert(U64Setting::MinProtocolVersion, try_read!(l, u64));
future::ok((u64s, try_read!(l, Regex)))
}).or_else(|_| -> future::FutureResult<(HashMap<U64Setting, u64>, Regex), ()> {
let mut u64s = HashMap::with_capacity(15);
- u64s.insert(U64Setting::ConnsPerSec, 10);
u64s.insert(U64Setting::RunTimeout, 120);
u64s.insert(U64Setting::WasGoodTimeout, 21600);
- u64s.insert(U64Setting::RescanInterval(AddressState::Untested), 0);
+ u64s.insert(U64Setting::RescanInterval(AddressState::Untested), 1);
u64s.insert(U64Setting::RescanInterval(AddressState::LowBlockCount), 3600);
u64s.insert(U64Setting::RescanInterval(AddressState::HighBlockCount), 7200);
u64s.insert(U64Setting::RescanInterval(AddressState::LowVersion), 21600);
for _ in 0..AddressState::get_count() {
state_vecs.push(Vec::new());
}
- let mut good_node_services = Vec::with_capacity(64);
- for _ in 0..64 {
- good_node_services.push(HashSet::new());
- }
+ let good_node_services = [HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new(), HashSet::new()];
Nodes {
good_node_services,
nodes_to_state: HashMap::new(),
}
let nodes_future = File::open(store.clone() + "/nodes").and_then(|f| {
+ let start_time = Instant::now() - Duration::from_secs(60 * 60 * 24);
let mut res = nodes_uninitd!();
let l = BufReader::new(f).lines();
for line_res in l {
last_services,
last_update: Instant::now(),
last_good: Instant::now(),
+ queued: true,
};
if node.state == AddressState::Good {
for i in 0..64 {
if node.last_services & (1 << i) != 0 {
- res.good_node_services[i].insert(sockaddr);
+ res.good_node_services[i].insert(sockaddr.into());
}
}
}
- res.state_next_scan[node.state.to_num() as usize].push((Instant::now(), sockaddr));
- res.nodes_to_state.insert(sockaddr, node);
+ res.state_next_scan[node.state.to_num() as usize].push((start_time, sockaddr.into()));
+ res.nodes_to_state.insert(sockaddr.into(), node);
}
future::ok(res)
}).or_else(|_| -> future::FutureResult<Nodes, ()> {
let mut nodes = self.nodes.write().unwrap();
let cur_time = Instant::now();
for addr in addresses {
- match nodes.nodes_to_state.entry(addr.clone()) {
+ match nodes.nodes_to_state.entry(addr.into()) {
hash_map::Entry::Vacant(e) => {
e.insert(Node {
state: AddressState::Untested,
last_services: 0,
last_update: cur_time,
last_good: cur_time,
+ queued: true,
});
- nodes.state_next_scan[AddressState::Untested.to_num() as usize].push((cur_time, addr));
+ nodes.state_next_scan[AddressState::Untested.to_num() as usize].push((cur_time, addr.into()));
res += 1;
},
hash_map::Entry::Occupied(_) => {},
}));
}
- pub fn set_node_state(&self, addr: SocketAddr, state: AddressState, services: u64) -> AddressState {
+ pub fn set_node_state(&self, sockaddr: SocketAddr, state: AddressState, services: u64) -> AddressState {
+ let addr: SockAddr = sockaddr.into();
+ let now = Instant::now();
+
let mut nodes_lock = self.nodes.write().unwrap();
let nodes = nodes_lock.borrow_mut();
- let now = Instant::now();
- let state_ref = nodes.nodes_to_state.entry(addr).or_insert(Node {
+ let state_ref = nodes.nodes_to_state.entry(addr.clone()).or_insert(Node {
state: AddressState::Untested,
last_services: 0,
last_update: now,
last_good: now,
+ queued: false,
});
let ret = state_ref.state;
if (state_ref.state == AddressState::Good || state_ref.state == AddressState::WasGood)
}
}
state_ref.last_services = 0;
- nodes.state_next_scan[AddressState::WasGood.to_num() as usize].push((now, addr));
+ if !state_ref.queued {
+ nodes.state_next_scan[AddressState::WasGood.to_num() as usize].push((now, addr));
+ state_ref.queued = true;
+ }
} else {
state_ref.state = state;
if state == AddressState::Good {
for i in 0..64 {
if services & (1 << i) != 0 && state_ref.last_services & (1 << i) == 0 {
- nodes.good_node_services[i].insert(addr);
+ nodes.good_node_services[i].insert(addr.clone());
} else if services & (1 << i) == 0 && state_ref.last_services & (1 << i) != 0 {
nodes.good_node_services[i].remove(&addr);
}
state_ref.last_services = services;
state_ref.last_good = now;
}
- nodes.state_next_scan[state.to_num() as usize].push((now, addr));
+ if !state_ref.queued {
+ nodes.state_next_scan[state.to_num() as usize].push((now, addr));
+ state_ref.queued = true;
+ }
}
state_ref.last_update = now;
ret
pub fn save_data(&'static self) -> impl Future<Item=(), Error=()> {
let settings_file = self.store.clone() + "/settings";
let settings_future = File::create(settings_file.clone() + ".tmp").and_then(move |f| {
- let settings_string = format!("{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}",
- self.get_u64(U64Setting::ConnsPerSec),
+ let settings_string = format!("{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}\n{}",
self.get_u64(U64Setting::RunTimeout),
self.get_u64(U64Setting::WasGoodTimeout),
self.get_u64(U64Setting::MinProtocolVersion),
let mut dns_buff = String::new();
{
let mut rng = thread_rng();
- for i in &[1u64, 4, 5, 8, 9, 12, 13, 1024, 1025, 1028, 1029, 1032, 1033, 1036, 1037] {
+ for i in &[ 0b00000000001u64,
+ 0b00000000100,
+ 0b00000000101,
+ 0b00000001000,
+ 0b00000001001,
+ 0b00000001100,
+ 0b00000001101,
+ 0b00001001001,
+ 0b10000000000,
+ 0b10000000001,
+ 0b10000000100,
+ 0b10000000101,
+ 0b10000001000,
+ 0b10000001001,
+ 0b10000001100,
+ 0b10000001101,
+ 0b10001001000] {
+ // ^ NODE_NETWORK_LIIMTED
+ //COMPACT_FILTERS ^ ^ NODE_BLOOM
+ // NODE_WITNESS ^ ^ NODE_NETWORK
+ // We support all combos of NETWORK, NETWORK_LIMITED, BLOOM, and WITNESS
+ // We support COMPACT_FILTERS with WITNESS and NETWORK or NETWORK_LIIMTED.
let mut tor_set: Vec<Ipv6Addr> = Vec::new();
let mut v6_set: Vec<Ipv6Addr> = Vec::new();
let mut v4_set: Vec<Ipv4Addr> = Vec::new();
}
pub fn get_next_scan_nodes(&self) -> Vec<SocketAddr> {
- let results = 30 * self.get_u64(U64Setting::ConnsPerSec) as usize;
- let per_bucket_results = results / (AddressState::get_count() as usize);
- let mut res = Vec::with_capacity(results);
+ let mut res = Vec::with_capacity(128);
let cur_time = Instant::now();
{
- let mut nodes = self.nodes.write().unwrap();
+ let mut nodes_lock = self.nodes.write().unwrap();
+ let nodes = nodes_lock.borrow_mut();
for (idx, state_nodes) in nodes.state_next_scan.iter_mut().enumerate() {
- let cmp_time = cur_time - Duration::from_secs(self.get_u64(U64Setting::RescanInterval(AddressState::from_num(idx as u8).unwrap())));
- let split_point = cmp::min(cmp::min(results - res.len(), (per_bucket_results * (idx + 1)) - res.len()),
- state_nodes.binary_search_by(|a| a.0.cmp(&cmp_time)).unwrap_or_else(|idx| idx));
- let mut new_nodes = state_nodes.split_off(split_point);
+ let rescan_interval = cmp::max(self.get_u64(U64Setting::RescanInterval(AddressState::from_num(idx as u8).unwrap())), 1);
+ let cmp_time = cur_time - Duration::from_secs(rescan_interval);
+ let split_point = cmp::min(cmp::min(SECS_PER_SCAN_RESULTS * state_nodes.len() as u64 / rescan_interval,
+ SECS_PER_SCAN_RESULTS * MAX_CONNS_PER_SEC_PER_STATUS),
+ state_nodes.binary_search_by(|a| a.0.cmp(&cmp_time)).unwrap_or_else(|idx| idx) as u64);
+ let mut new_nodes = state_nodes.split_off(split_point as usize);
mem::swap(&mut new_nodes, state_nodes);
for (_, node) in new_nodes.drain(..) {
- res.push(node);
+ nodes.nodes_to_state.get_mut(&node).unwrap().queued = false;
+ res.push((&node).into());
}
}
}