//! Module containing structs related to membership management
use std::collections::HashMap;
use std::io::{Read, Write};
use std::net::{IpAddr, SocketAddr};
use std::path::{Path, PathBuf};
use std::sync::{Arc, RwLock};
use std::time::{Duration, Instant};
use arc_swap::ArcSwapOption;
use async_trait::async_trait;
use futures::join;
use serde::{Deserialize, Serialize};
use sodiumoxide::crypto::sign::ed25519;
use tokio::select;
use tokio::sync::watch;
use tokio::sync::Mutex;
use garage_net::endpoint::{Endpoint, EndpointHandler};
use garage_net::message::*;
use garage_net::peering::PeeringManager;
use garage_net::util::parse_and_resolve_peer_addr_async;
use garage_net::{NetApp, NetworkKey, NodeID, NodeKey};
#[cfg(feature = "kubernetes-discovery")]
use garage_util::config::KubernetesDiscoveryConfig;
use garage_util::config::{Config, DataDirEnum};
use garage_util::data::*;
use garage_util::error::*;
use garage_util::persister::Persister;
use garage_util::time::*;
#[cfg(feature = "consul-discovery")]
use crate::consul::ConsulDiscovery;
#[cfg(feature = "kubernetes-discovery")]
use crate::kubernetes::*;
use crate::layout::*;
use crate::replication_mode::*;
use crate::ring::*;
use crate::rpc_helper::*;
use crate::system_metrics::*;
const DISCOVERY_INTERVAL: Duration = Duration::from_secs(60);
const STATUS_EXCHANGE_INTERVAL: Duration = Duration::from_secs(10);
/// Version tag used for version check upon Netapp connection.
/// Cluster nodes with different version tags are deemed
/// incompatible and will refuse to connect.
pub const GARAGE_VERSION_TAG: u64 = 0x6761726167650008; // garage 0x0008
/// RPC endpoint used for calls related to membership
pub const SYSTEM_RPC_PATH: &str = "garage_rpc/membership.rs/SystemRpc";
/// RPC messages related to membership
#[derive(Debug, Serialize, Deserialize, Clone)]
pub enum SystemRpc {
/// Response to successfull advertisements
Ok,
/// Request to connect to a specific node (in <pubkey>@<host>:<port> format, pubkey = full-length node ID)
Connect(String),
/// Ask other node its cluster layout. Answered with AdvertiseClusterLayout
PullClusterLayout,
/// Advertise Garage status. Answered with another AdvertiseStatus.
/// Exchanged with every node on a regular basis.
AdvertiseStatus(NodeStatus),
/// Advertisement of cluster layout. Sent spontanously or in response to PullClusterLayout
AdvertiseClusterLayout(ClusterLayout),
/// Get known nodes states
GetKnownNodes,
/// Return known nodes
ReturnKnownNodes(Vec<KnownNodeInfo>),
}
impl Rpc for SystemRpc {
type Response = Result<SystemRpc, Error>;
}
#[derive(Serialize, Deserialize)]
pub struct PeerList(Vec<(Uuid, SocketAddr)>);
impl garage_util::migrate::InitialFormat for PeerList {}
/// This node's membership manager
pub struct System {
/// The id of this node
pub id: Uuid,
persist_cluster_layout: Persister<ClusterLayout>,
persist_peer_list: Persister<PeerList>,
pub(crate) local_status: RwLock<NodeStatus>,
node_status: RwLock<HashMap<Uuid, (u64, NodeStatus)>>,
pub netapp: Arc<NetApp>,
peering: Arc<PeeringManager>,
pub rpc: RpcHelper,
system_endpoint: Arc<Endpoint<SystemRpc, System>>,
rpc_listen_addr: SocketAddr,
rpc_public_addr: Option<SocketAddr>,
bootstrap_peers: Vec<String>,
#[cfg(feature = "consul-discovery")]
consul_discovery: Option<ConsulDiscovery>,
#[cfg(feature = "kubernetes-discovery")]
kubernetes_discovery: Option<KubernetesDiscoveryConfig>,
metrics: ArcSwapOption<SystemMetrics>,
replication_mode: ReplicationMode,
pub(crate) replication_factor: usize,
/// The ring
pub ring: watch::Receiver<Arc<Ring>>,
update_ring: Mutex<watch::Sender<Arc<Ring>>>,
/// Path to metadata directory
pub metadata_dir: PathBuf,
/// Path to data directory
pub data_dir: DataDirEnum,
}
#[derive(Debug, Clone, Serialize, Deserialize)]
pub struct NodeStatus {
/// Hostname of the node
pub hostname: String,
/// Replication factor configured on the node
pub replication_factor: usize,
/// Cluster layout version
pub cluster_layout_version: u64,
/// Hash of cluster layout staging data
pub cluster_layout_staging_hash: Hash,
/// Disk usage on partition containing metadata directory (tuple: `(avail, total)`)
#[serde(default)]
pub meta_disk_avail: Option<(u64, u64)>,
/// Disk usage on partition containing data directory (tuple: `(avail, total)`)
#[serde(default)]
pub data_disk_avail: Option<(u64, u64)>,
}
#[derive(Debug, Clone, Serialize, Deserialize)]
pub struct KnownNodeInfo {
pub id: Uuid,
pub addr: SocketAddr,
pub is_up: bool,
pub last_seen_secs_ago: Option<u64>,
pub status: NodeStatus,
}
#[derive(Debug, Clone, Copy)]
pub struct ClusterHealth {
/// The current health status of the cluster (see below)
pub status: ClusterHealthStatus,
/// Number of nodes already seen once in the cluster
pub known_nodes: usize,
/// Number of nodes currently connected
pub connected_nodes: usize,
/// Number of storage nodes declared in the current layout
pub storage_nodes: usize,
/// Number of storage nodes currently connected
pub storage_nodes_ok: usize,
/// Number of partitions in the layout
pub partitions: usize,
/// Number of partitions for which we have a quorum of connected nodes
pub partitions_quorum: usize,
/// Number of partitions for which all storage nodes are connected
pub partitions_all_ok: usize,
}
#[derive(Debug, Clone, Copy, Eq, PartialEq)]
pub enum ClusterHealthStatus {
/// All nodes are available
Healthy,
/// Some storage nodes are unavailable, but quorum is stil
/// achieved for all partitions
Degraded,
/// Quorum is not available for some partitions
Unavailable,
}
pub fn read_node_id(metadata_dir: &Path) -> Result<NodeID, Error> {
let mut pubkey_file = metadata_dir.to_path_buf();
pubkey_file.push("node_key.pub");
let mut f = std::fs::File::open(pubkey_file.as_path())?;
let mut d = vec![];
f.read_to_end(&mut d)?;
if d.len() != 32 {
return Err(Error::Message("Corrupt node_key.pub file".to_string()));
}
let mut key = [0u8; 32];
key.copy_from_slice(&d[..]);
Ok(NodeID::from_slice(&key[..]).unwrap())
}
pub fn gen_node_key(metadata_dir: &Path) -> Result<NodeKey, Error> {
let mut key_file = metadata_dir.to_path_buf();
key_file.push("node_key");
if key_file.as_path().exists() {
let mut f = std::fs::File::open(key_file.as_path())?;
let mut d = vec![];
f.read_to_end(&mut d)?;
if d.len() != 64 {
return Err(Error::Message("Corrupt node_key file".to_string()));
}
let mut key = [0u8; 64];
key.copy_from_slice(&d[..]);
Ok(NodeKey::from_slice(&key[..]).unwrap())
} else {
if !metadata_dir.exists() {
info!("Metadata directory does not exist, creating it.");
std::fs::create_dir(metadata_dir)?;
}
info!("Generating new node key pair.");
let (pubkey, key) = ed25519::gen_keypair();
{
use std::os::unix::fs::PermissionsExt;
let mut f = std::fs::File::create(key_file.as_path())?;
let mut perm = f.metadata()?.permissions();
perm.set_mode(0o600);
std::fs::set_permissions(key_file.as_path(), perm)?;
f.write_all(&key[..])?;
}
{
let mut pubkey_file = metadata_dir.to_path_buf();
pubkey_file.push("node_key.pub");
let mut f2 = std::fs::File::create(pubkey_file.as_path())?;
f2.write_all(&pubkey[..])?;
}
Ok(key)
}
}
impl System {
/// Create this node's membership manager
pub fn new(
network_key: NetworkKey,
replication_mode: ReplicationMode,
config: &Config,
) -> Result<Arc<Self>, Error> {
let replication_factor = replication_mode.replication_factor();
let node_key =
gen_node_key(&config.metadata_dir).expect("Unable to read or generate node ID");
info!(
"Node ID of this node: {}",
hex::encode(&node_key.public_key()[..8])
);
let persist_cluster_layout: Persister<ClusterLayout> =
Persister::new(&config.metadata_dir, "cluster_layout");
let persist_peer_list = Persister::new(&config.metadata_dir, "peer_list");
let cluster_layout = match persist_cluster_layout.load() {
Ok(x) => {
if x.replication_factor != replication_factor {
return Err(Error::Message(format!(
"Prevous cluster layout has replication factor {}, which is different than the one specified in the config file ({}). The previous cluster layout can be purged, if you know what you are doing, simply by deleting the `cluster_layout` file in your metadata directory.",
x.replication_factor,
replication_factor
)));
}
x
}
Err(e) => {
info!(
"No valid previous cluster layout stored ({}), starting fresh.",
e
);
ClusterLayout::new(replication_factor)
}
};
let mut local_status = NodeStatus::initial(replication_factor, &cluster_layout);
local_status.update_disk_usage(&config.metadata_dir, &config.data_dir);
let ring = Ring::new(cluster_layout, replication_factor);
let (update_ring, ring) = watch::channel(Arc::new(ring));
let rpc_public_addr = match &config.rpc_public_addr {
Some(a_str) => {
use std::net::ToSocketAddrs;
match a_str.to_socket_addrs() {
Err(e) => {
error!(
"Cannot resolve rpc_public_addr {} from config file: {}.",
a_str, e
);
None
}
Ok(a) => {
let a = a.collect::<Vec<_>>();
if a.is_empty() {
error!("rpc_public_addr {} resolve to no known IP address", a_str);
}
if a.len() > 1 {
warn!("Multiple possible resolutions for rpc_public_addr: {:?}. Taking the first one.", a);
}
a.into_iter().next()
}
}
}
None => {
let addr =
get_default_ip().map(|ip| SocketAddr::new(ip, config.rpc_bind_addr.port()));
if let Some(a) = addr {
warn!("Using autodetected rpc_public_addr: {}. Consider specifying it explicitly in configuration file if possible.", a);
}
addr
}
};
if rpc_public_addr.is_none() {
warn!("This Garage node does not know its publicly reachable RPC address, this might hamper intra-cluster communication.");
}
let bind_outgoing_to = Some(config)
.filter(|x| x.rpc_bind_outgoing)
.map(|x| x.rpc_bind_addr.ip());
let netapp = NetApp::new(GARAGE_VERSION_TAG, network_key, node_key, bind_outgoing_to);
let peering = PeeringManager::new(netapp.clone(), vec![], rpc_public_addr);
if let Some(ping_timeout) = config.rpc_ping_timeout_msec {
peering.set_ping_timeout_millis(ping_timeout);
}
let system_endpoint = netapp.endpoint(SYSTEM_RPC_PATH.into());
#[cfg(feature = "consul-discovery")]
let consul_discovery = match &config.consul_discovery {
Some(cfg) => Some(
ConsulDiscovery::new(cfg.clone())
.ok_or_message("Invalid Consul discovery configuration")?,
),
None => None,
};
#[cfg(not(feature = "consul-discovery"))]
if config.consul_discovery.is_some() {
warn!("Consul discovery is not enabled in this build.");
}
#[cfg(not(feature = "kubernetes-discovery"))]
if config.kubernetes_discovery.is_some() {
warn!("Kubernetes discovery is not enabled in this build.");
}
let sys = Arc::new(System {
id: netapp.id.into(),
persist_cluster_layout,
persist_peer_list,
local_status: RwLock::new(local_status),
node_status: RwLock::new(HashMap::new()),
netapp: netapp.clone(),
peering: peering.clone(),
rpc: RpcHelper::new(
netapp.id.into(),
peering,
ring.clone(),
config.rpc_timeout_msec.map(Duration::from_millis),
),
system_endpoint,
replication_mode,
replication_factor,
rpc_listen_addr: config.rpc_bind_addr,
rpc_public_addr,
bootstrap_peers: config.bootstrap_peers.clone(),
#[cfg(feature = "consul-discovery")]
consul_discovery,
#[cfg(feature = "kubernetes-discovery")]
kubernetes_discovery: config.kubernetes_discovery.clone(),
metrics: ArcSwapOption::new(None),
ring,
update_ring: Mutex::new(update_ring),
metadata_dir: config.metadata_dir.clone(),
data_dir: config.data_dir.clone(),
});
sys.system_endpoint.set_handler(sys.clone());
let metrics = SystemMetrics::new(sys.clone());
sys.metrics.store(Some(Arc::new(metrics)));
Ok(sys)
}
/// Perform bootstraping, starting the ping loop
pub async fn run(self: Arc<Self>, must_exit: watch::Receiver<bool>) {
join!(
self.netapp.clone().listen(
self.rpc_listen_addr,
self.rpc_public_addr,
must_exit.clone()
),
self.peering.clone().run(must_exit.clone()),
self.discovery_loop(must_exit.clone()),
self.status_exchange_loop(must_exit.clone()),
);
}
pub fn cleanup(&self) {
// Break reference cycle
self.metrics.store(None);
}
// ---- Administrative operations (directly available and
// also available through RPC) ----
pub fn get_known_nodes(&self) -> Vec<KnownNodeInfo> {
let node_status = self.node_status.read().unwrap();
let known_nodes = self
.peering
.get_peer_list()
.iter()
.map(|n| KnownNodeInfo {
id: n.id.into(),
addr: n.addr,
is_up: n.is_up(),
last_seen_secs_ago: n
.last_seen
.map(|t| (Instant::now().saturating_duration_since(t)).as_secs()),
status: node_status
.get(&n.id.into())
.cloned()
.map(|(_, st)| st)
.unwrap_or_else(NodeStatus::unknown),
})
.collect::<Vec<_>>();
known_nodes
}
pub fn get_cluster_layout(&self) -> ClusterLayout {
self.ring.borrow().layout.clone()
}
pub async fn update_cluster_layout(
self: &Arc<Self>,
layout: &ClusterLayout,
) -> Result<(), Error> {
self.handle_advertise_cluster_layout(layout).await?;
Ok(())
}
pub async fn connect(&self, node: &str) -> Result<(), Error> {
let (pubkey, addrs) = parse_and_resolve_peer_addr_async(node)
.await
.ok_or_else(|| {
Error::Message(format!(
"Unable to parse or resolve node specification: {}",
node
))
})?;
let mut errors = vec![];
for addr in addrs.iter() {
match self.netapp.clone().try_connect(*addr, pubkey).await {
Ok(()) => return Ok(()),
Err(e) => {
errors.push((
*addr,
Error::Message(connect_error_message(*addr, pubkey, e)),
));
}
}
}
if errors.len() == 1 {
Err(Error::Message(errors[0].1.to_string()))
} else {
Err(Error::Message(format!("{:?}", errors)))
}
}
pub fn health(&self) -> ClusterHealth {
let ring: Arc<_> = self.ring.borrow().clone();
let quorum = self.replication_mode.write_quorum();
let replication_factor = self.replication_factor;
let nodes = self
.get_known_nodes()
.into_iter()
.map(|n| (n.id, n))
.collect::<HashMap<Uuid, _>>();
let connected_nodes = nodes.iter().filter(|(_, n)| n.is_up).count();
let storage_nodes = ring
.layout
.roles
.items()
.iter()
.filter(|(_, _, v)| matches!(v, NodeRoleV(Some(r)) if r.capacity.is_some()))
.collect::<Vec<_>>();
let storage_nodes_ok = storage_nodes
.iter()
.filter(|(x, _, _)| nodes.get(x).map(|n| n.is_up).unwrap_or(false))
.count();
let partitions = ring.partitions();
let partitions_n_up = partitions
.iter()
.map(|(_, h)| {
let pn = ring.get_nodes(h, ring.replication_factor);
pn.iter()
.filter(|x| nodes.get(x).map(|n| n.is_up).unwrap_or(false))
.count()
})
.collect::<Vec<usize>>();
let partitions_all_ok = partitions_n_up
.iter()
.filter(|c| **c == replication_factor)
.count();
let partitions_quorum = partitions_n_up.iter().filter(|c| **c >= quorum).count();
let status =
if partitions_quorum == partitions.len() && storage_nodes_ok == storage_nodes.len() {
ClusterHealthStatus::Healthy
} else if partitions_quorum == partitions.len() {
ClusterHealthStatus::Degraded
} else {
ClusterHealthStatus::Unavailable
};
ClusterHealth {
status,
known_nodes: nodes.len(),
connected_nodes,
storage_nodes: storage_nodes.len(),
storage_nodes_ok,
partitions: partitions.len(),
partitions_quorum,
partitions_all_ok,
}
}
// ---- INTERNALS ----
#[cfg(feature = "consul-discovery")]
async fn advertise_to_consul(self: Arc<Self>) {
let c = match &self.consul_discovery {
Some(c) => c,
_ => return,
};
let rpc_public_addr = match self.rpc_public_addr {
Some(addr) => addr,
None => {
warn!("Not advertising to Consul because rpc_public_addr is not defined in config file and could not be autodetected.");
return;
}
};
let hostname = self.local_status.read().unwrap().hostname.clone();
if let Err(e) = c
.publish_consul_service(self.netapp.id, &hostname, rpc_public_addr)
.await
{
error!("Error while publishing Consul service: {}", e);
}
}
#[cfg(feature = "kubernetes-discovery")]
async fn advertise_to_kubernetes(self: Arc<Self>) {
let k = match &self.kubernetes_discovery {
Some(k) => k,
_ => return,
};
let rpc_public_addr = match self.rpc_public_addr {
Some(addr) => addr,
None => {
warn!("Not advertising to Kubernetes because rpc_public_addr is not defined in config file and could not be autodetected.");
return;
}
};
let hostname = self.local_status.read().unwrap().hostname.clone();
if let Err(e) = publish_kubernetes_node(k, self.netapp.id, &hostname, rpc_public_addr).await
{
error!("Error while publishing node to Kubernetes: {}", e);
}
}
/// Save network configuration to disc
async fn save_cluster_layout(&self) -> Result<(), Error> {
let ring: Arc<Ring> = self.ring.borrow().clone();
self.persist_cluster_layout
.save_async(&ring.layout)
.await
.expect("Cannot save current cluster layout");
Ok(())
}
fn update_local_status(&self) {
let mut local_status = self.local_status.write().unwrap();
let ring = self.ring.borrow();
local_status.cluster_layout_version = ring.layout.version;
local_status.cluster_layout_staging_hash = ring.layout.staging_hash;
local_status.update_disk_usage(&self.metadata_dir, &self.data_dir);
}
// --- RPC HANDLERS ---
async fn handle_connect(&self, node: &str) -> Result<SystemRpc, Error> {
self.connect(node).await?;
Ok(SystemRpc::Ok)
}
fn handle_pull_cluster_layout(&self) -> SystemRpc {
let ring = self.ring.borrow().clone();
SystemRpc::AdvertiseClusterLayout(ring.layout.clone())
}
fn handle_get_known_nodes(&self) -> SystemRpc {
let known_nodes = self.get_known_nodes();
SystemRpc::ReturnKnownNodes(known_nodes)
}
async fn handle_advertise_status(
self: &Arc<Self>,
from: Uuid,
info: &NodeStatus,
) -> Result<SystemRpc, Error> {
let local_info = self.local_status.read().unwrap();
if local_info.replication_factor < info.replication_factor {
error!("Some node have a higher replication factor ({}) than this one ({}). This is not supported and will lead to data corruption. Shutting down for safety.",
info.replication_factor,
local_info.replication_factor);
std::process::exit(1);
}
if info.cluster_layout_version > local_info.cluster_layout_version
|| info.cluster_layout_staging_hash != local_info.cluster_layout_staging_hash
{
tokio::spawn(self.clone().pull_cluster_layout(from));
}
drop(local_info);
self.node_status
.write()
.unwrap()
.insert(from, (now_msec(), info.clone()));
Ok(SystemRpc::Ok)
}
async fn handle_advertise_cluster_layout(
self: &Arc<Self>,
adv: &ClusterLayout,
) -> Result<SystemRpc, Error> {
if adv.replication_factor != self.replication_factor {
let msg = format!(
"Received a cluster layout from another node with replication factor {}, which is different from what we have in our configuration ({}). Discarding the cluster layout we received.",
adv.replication_factor,
self.replication_factor
);
error!("{}", msg);
return Err(Error::Message(msg));
}
let update_ring = self.update_ring.lock().await;
let mut layout: ClusterLayout = self.ring.borrow().layout.clone();
let prev_layout_check = layout.check().is_ok();
if layout.merge(adv) {
if prev_layout_check && layout.check().is_err() {
error!("New cluster layout is invalid, discarding.");
return Err(Error::Message(
"New cluster layout is invalid, discarding.".into(),
));
}
let ring = Ring::new(layout.clone(), self.replication_factor);
update_ring.send(Arc::new(ring))?;
drop(update_ring);
let self2 = self.clone();
tokio::spawn(async move {
if let Err(e) = self2
.rpc
.broadcast(
&self2.system_endpoint,
SystemRpc::AdvertiseClusterLayout(layout),
RequestStrategy::with_priority(PRIO_HIGH),
)
.await
{
warn!("Error while broadcasting new cluster layout: {}", e);
}
});
self.save_cluster_layout().await?;
}
Ok(SystemRpc::Ok)
}
async fn status_exchange_loop(&self, mut stop_signal: watch::Receiver<bool>) {
while !*stop_signal.borrow() {
let restart_at = Instant::now() + STATUS_EXCHANGE_INTERVAL;
// Update local node status that is exchanged.
self.update_local_status();
let local_status: NodeStatus = self.local_status.read().unwrap().clone();
let _ = self
.rpc
.broadcast(
&self.system_endpoint,
SystemRpc::AdvertiseStatus(local_status),
RequestStrategy::with_priority(PRIO_HIGH)
.with_custom_timeout(STATUS_EXCHANGE_INTERVAL),
)
.await;
select! {
_ = tokio::time::sleep_until(restart_at.into()) => {},
_ = stop_signal.changed() => {},
}
}
}
async fn discovery_loop(self: &Arc<Self>, mut stop_signal: watch::Receiver<bool>) {
while !*stop_signal.borrow() {
let n_connected = self
.peering
.get_peer_list()
.iter()
.filter(|p| p.is_up())
.count();
let not_configured = self.ring.borrow().layout.check().is_err();
let no_peers = n_connected < self.replication_factor;
let expected_n_nodes = self.ring.borrow().layout.num_nodes();
let bad_peers = n_connected != expected_n_nodes;
if not_configured || no_peers || bad_peers {
info!("Doing a bootstrap/discovery step (not_configured: {}, no_peers: {}, bad_peers: {})", not_configured, no_peers, bad_peers);
let mut ping_list = resolve_peers(&self.bootstrap_peers).await;
// Add peer list from list stored on disk
if let Ok(peers) = self.persist_peer_list.load_async().await {
ping_list.extend(peers.0.iter().map(|(id, addr)| ((*id).into(), *addr)))
}
// Fetch peer list from Consul
#[cfg(feature = "consul-discovery")]
if let Some(c) = &self.consul_discovery {
match c.get_consul_nodes().await {
Ok(node_list) => {
ping_list.extend(node_list);
}
Err(e) => {
warn!("Could not retrieve node list from Consul: {}", e);
}
}
}
// Fetch peer list from Kubernetes
#[cfg(feature = "kubernetes-discovery")]
if let Some(k) = &self.kubernetes_discovery {
if !k.skip_crd {
match create_kubernetes_crd().await {
Ok(()) => (),
Err(e) => {
error!("Failed to create kubernetes custom resource: {}", e)
}
};
}
match get_kubernetes_nodes(k).await {
Ok(node_list) => {
ping_list.extend(node_list);
}
Err(e) => {
warn!("Could not retrieve node list from Kubernetes: {}", e);
}
}
}
if !not_configured && !no_peers {
// If the layout is configured, and we already have some connections
// to other nodes in the cluster, we can skip trying to connect to
// nodes that are not in the cluster layout.
let ring = self.ring.borrow();
ping_list.retain(|(id, _)| ring.layout.node_ids().contains(&(*id).into()));
}
for (node_id, node_addr) in ping_list {
let self2 = self.clone();
tokio::spawn(async move {
if let Err(e) = self2.netapp.clone().try_connect(node_addr, node_id).await {
error!("{}", connect_error_message(node_addr, node_id, e));
}
});
}
}
if let Err(e) = self.save_peer_list().await {
warn!("Could not save peer list to file: {}", e);
}
#[cfg(feature = "consul-discovery")]
tokio::spawn(self.clone().advertise_to_consul());
#[cfg(feature = "kubernetes-discovery")]
tokio::spawn(self.clone().advertise_to_kubernetes());
select! {
_ = tokio::time::sleep(DISCOVERY_INTERVAL) => {},
_ = stop_signal.changed() => {},
}
}
}
async fn save_peer_list(&self) -> Result<(), Error> {
// Prepare new peer list to save to file
// It is a vec of tuples (node ID as Uuid, node SocketAddr)
let mut peer_list = self
.peering
.get_peer_list()
.iter()
.map(|n| (n.id.into(), n.addr))
.collect::<Vec<_>>();
// Before doing it, we read the current peer list file (if it exists)
// and append it to the list we are about to save,
// so that no peer ID gets lost in the process.
if let Ok(mut prev_peer_list) = self.persist_peer_list.load_async().await {
prev_peer_list
.0
.retain(|(id, _ip)| peer_list.iter().all(|(id2, _ip2)| id2 != id));
peer_list.extend(prev_peer_list.0);
}
// Save new peer list to file
self.persist_peer_list
.save_async(&PeerList(peer_list))
.await
}
async fn pull_cluster_layout(self: Arc<Self>, peer: Uuid) {
let resp = self
.rpc
.call(
&self.system_endpoint,
peer,
SystemRpc::PullClusterLayout,
RequestStrategy::with_priority(PRIO_HIGH),
)
.await;
if let Ok(SystemRpc::AdvertiseClusterLayout(layout)) = resp {
let _: Result<_, _> = self.handle_advertise_cluster_layout(&layout).await;
}
}
}
#[async_trait]
impl EndpointHandler<SystemRpc> for System {
async fn handle(self: &Arc<Self>, msg: &SystemRpc, from: NodeID) -> Result<SystemRpc, Error> {
match msg {
SystemRpc::Connect(node) => self.handle_connect(node).await,
SystemRpc::PullClusterLayout => Ok(self.handle_pull_cluster_layout()),
SystemRpc::AdvertiseStatus(adv) => self.handle_advertise_status(from.into(), adv).await,
SystemRpc::AdvertiseClusterLayout(adv) => {
self.clone().handle_advertise_cluster_layout(adv).await
}
SystemRpc::GetKnownNodes => Ok(self.handle_get_known_nodes()),
m => Err(Error::unexpected_rpc_message(m)),
}
}
}
impl NodeStatus {
fn initial(replication_factor: usize, layout: &ClusterLayout) -> Self {
NodeStatus {
hostname: gethostname::gethostname()
.into_string()
.unwrap_or_else(|_| "<invalid utf-8>".to_string()),
replication_factor,
cluster_layout_version: layout.version,
cluster_layout_staging_hash: layout.staging_hash,
meta_disk_avail: None,
data_disk_avail: None,
}
}
fn unknown() -> Self {
NodeStatus {
hostname: "?".to_string(),
replication_factor: 0,
cluster_layout_version: 0,
cluster_layout_staging_hash: Hash::from([0u8; 32]),
meta_disk_avail: None,
data_disk_avail: None,
}
}
fn update_disk_usage(&mut self, meta_dir: &Path, data_dir: &DataDirEnum) {
use nix::sys::statvfs::statvfs;
let mount_avail = |path: &Path| match statvfs(path) {
Ok(x) => {
let avail = x.blocks_available() as u64 * x.fragment_size() as u64;
let total = x.blocks() as u64 * x.fragment_size() as u64;
Some((x.filesystem_id(), avail, total))
}
Err(_) => None,
};
self.meta_disk_avail = mount_avail(meta_dir).map(|(_, a, t)| (a, t));
self.data_disk_avail = match data_dir {
DataDirEnum::Single(dir) => mount_avail(dir).map(|(_, a, t)| (a, t)),
DataDirEnum::Multiple(dirs) => (|| {
// TODO: more precise calculation that takes into account
// how data is going to be spread among partitions
let mut mounts = HashMap::new();
for dir in dirs.iter() {
if dir.capacity.is_none() {
continue;
}
match mount_avail(&dir.path) {
Some((fsid, avail, total)) => {
mounts.insert(fsid, (avail, total));
}
None => return None,
}
}
Some(
mounts
.into_iter()
.fold((0, 0), |(x, y), (_, (a, b))| (x + a, y + b)),
)
})(),
};
}
}
fn get_default_ip() -> Option<IpAddr> {
pnet_datalink::interfaces()
.iter()
.find(|e| e.is_up() && !e.is_loopback() && !e.ips.is_empty())
.and_then(|e| e.ips.first())
.map(|a| a.ip())
}
async fn resolve_peers(peers: &[String]) -> Vec<(NodeID, SocketAddr)> {
let mut ret = vec![];
for peer in peers.iter() {
match parse_and_resolve_peer_addr_async(peer).await {
Some((pubkey, addrs)) => {
for ip in addrs {
ret.push((pubkey, ip));
}
}
None => {
warn!("Unable to parse and/or resolve peer hostname {}", peer);
}
}
}
ret
}
fn connect_error_message(
addr: SocketAddr,
pubkey: ed25519::PublicKey,
e: garage_net::error::Error,
) -> String {
format!("Error establishing RPC connection to remote node: {}@{}.\nThis can happen if the remote node is not reachable on the network, but also if the two nodes are not configured with the same rpc_secret.\n{}", hex::encode(pubkey), addr, e)
}