use std::collections::HashMap;
use std::fmt::Write;
use std::sync::Arc;
use serde::{Deserialize, Serialize};
use garage_util::error::Error;
use garage_table::crdt::CRDT;
use garage_table::replication::*;
use garage_table::*;
use garage_rpc::rpc_client::*;
use garage_rpc::rpc_server::*;
use garage_model::bucket_table::*;
use garage_model::garage::Garage;
use garage_model::key_table::*;
use crate::cli::*;
use crate::repair::Repair;
use crate::*;
pub const ADMIN_RPC_TIMEOUT: Duration = Duration::from_secs(30);
pub const ADMIN_RPC_PATH: &str = "_admin";
#[derive(Debug, Serialize, Deserialize)]
pub enum AdminRPC {
BucketOperation(BucketOperation),
KeyOperation(KeyOperation),
LaunchRepair(RepairOpt),
Stats(StatsOpt),
// Replies
Ok(String),
BucketList(Vec<String>),
BucketInfo(Bucket),
KeyList(Vec<(String, String)>),
KeyInfo(Key),
}
impl RpcMessage for AdminRPC {}
pub struct AdminRpcHandler {
garage: Arc<Garage>,
rpc_client: Arc<RpcClient<AdminRPC>>,
}
impl AdminRpcHandler {
pub fn new(garage: Arc<Garage>) -> Arc<Self> {
let rpc_client = garage.system.clone().rpc_client::<AdminRPC>(ADMIN_RPC_PATH);
Arc::new(Self { garage, rpc_client })
}
pub fn register_handler(self: Arc<Self>, rpc_server: &mut RpcServer) {
rpc_server.add_handler::<AdminRPC, _, _>(ADMIN_RPC_PATH.to_string(), move |msg, _addr| {
let self2 = self.clone();
async move {
match msg {
AdminRPC::BucketOperation(bo) => self2.handle_bucket_cmd(bo).await,
AdminRPC::KeyOperation(ko) => self2.handle_key_cmd(ko).await,
AdminRPC::LaunchRepair(opt) => self2.handle_launch_repair(opt).await,
AdminRPC::Stats(opt) => self2.handle_stats(opt).await,
_ => Err(Error::BadRPC(format!("Invalid RPC"))),
}
}
});
}
async fn handle_bucket_cmd(&self, cmd: BucketOperation) -> Result<AdminRPC, Error> {
match cmd {
BucketOperation::List => {
let bucket_names = self
.garage
.bucket_table
.get_range(&EmptyKey, None, Some(DeletedFilter::NotDeleted), 10000)
.await?
.iter()
.map(|b| b.name.to_string())
.collect::<Vec<_>>();
Ok(AdminRPC::BucketList(bucket_names))
}
BucketOperation::Info(query) => {
let bucket = self.get_existing_bucket(&query.name).await?;
Ok(AdminRPC::BucketInfo(bucket))
}
BucketOperation::Create(query) => {
let bucket = match self.garage.bucket_table.get(&EmptyKey, &query.name).await? {
Some(mut bucket) => {
if !bucket.is_deleted() {
return Err(Error::BadRPC(format!(
"Bucket {} already exists",
query.name
)));
}
bucket
.state
.update(BucketState::Present(BucketParams::new()));
bucket
}
None => Bucket::new(query.name.clone()),
};
self.garage.bucket_table.insert(&bucket).await?;
Ok(AdminRPC::Ok(format!("Bucket {} was created.", query.name)))
}
BucketOperation::Delete(query) => {
let mut bucket = self.get_existing_bucket(&query.name).await?;
let objects = self
.garage
.object_table
.get_range(&query.name, None, Some(DeletedFilter::NotDeleted), 10)
.await?;
if !objects.is_empty() {
return Err(Error::BadRPC(format!("Bucket {} is not empty", query.name)));
}
if !query.yes {
return Err(Error::BadRPC(format!(
"Add --yes flag to really perform this operation"
)));
}
// --- done checking, now commit ---
for (key_id, _, _) in bucket.authorized_keys() {
if let Some(key) = self.garage.key_table.get(&EmptyKey, key_id).await? {
if !key.deleted.get() {
self.update_key_bucket(&key, &bucket.name, false, false)
.await?;
}
} else {
return Err(Error::Message(format!("Key not found: {}", key_id)));
}
}
bucket.state.update(BucketState::Deleted);
self.garage.bucket_table.insert(&bucket).await?;
Ok(AdminRPC::Ok(format!("Bucket {} was deleted.", query.name)))
}
BucketOperation::Allow(query) => {
let key = self.get_existing_key(&query.key_pattern).await?;
let bucket = self.get_existing_bucket(&query.bucket).await?;
let allow_read = query.read || key.allow_read(&query.bucket);
let allow_write = query.write || key.allow_write(&query.bucket);
self.update_key_bucket(&key, &query.bucket, allow_read, allow_write)
.await?;
self.update_bucket_key(bucket, &key.key_id, allow_read, allow_write)
.await?;
Ok(AdminRPC::Ok(format!(
"New permissions for {} on {}: read {}, write {}.",
&key.key_id, &query.bucket, allow_read, allow_write
)))
}
BucketOperation::Deny(query) => {
let key = self.get_existing_key(&query.key_pattern).await?;
let bucket = self.get_existing_bucket(&query.bucket).await?;
let allow_read = !query.read && key.allow_read(&query.bucket);
let allow_write = !query.write && key.allow_write(&query.bucket);
self.update_key_bucket(&key, &query.bucket, allow_read, allow_write)
.await?;
self.update_bucket_key(bucket, &key.key_id, allow_read, allow_write)
.await?;
Ok(AdminRPC::Ok(format!(
"New permissions for {} on {}: read {}, write {}.",
&key.key_id, &query.bucket, allow_read, allow_write
)))
}
BucketOperation::Website(query) => {
let mut bucket = self.get_existing_bucket(&query.bucket).await?;
if !(query.allow ^ query.deny) {
return Err(Error::Message(format!(
"You must specify exactly one flag, either --allow or --deny"
)));
}
if let BucketState::Present(state) = bucket.state.get_mut() {
state.website.update(query.allow);
self.garage.bucket_table.insert(&bucket).await?;
let msg = if query.allow {
format!("Website access allowed for {}", &query.bucket)
} else {
format!("Website access denied for {}", &query.bucket)
};
Ok(AdminRPC::Ok(msg.to_string()))
} else {
unreachable!();
}
}
}
}
async fn handle_key_cmd(&self, cmd: KeyOperation) -> Result<AdminRPC, Error> {
match cmd {
KeyOperation::List => {
let key_ids = self
.garage
.key_table
.get_range(
&EmptyKey,
None,
Some(KeyFilter::Deleted(DeletedFilter::NotDeleted)),
10000,
)
.await?
.iter()
.map(|k| (k.key_id.to_string(), k.name.get().clone()))
.collect::<Vec<_>>();
Ok(AdminRPC::KeyList(key_ids))
}
KeyOperation::Info(query) => {
let key = self.get_existing_key(&query.key_pattern).await?;
Ok(AdminRPC::KeyInfo(key))
}
KeyOperation::New(query) => {
let key = Key::new(query.name);
self.garage.key_table.insert(&key).await?;
Ok(AdminRPC::KeyInfo(key))
}
KeyOperation::Rename(query) => {
let mut key = self.get_existing_key(&query.key_pattern).await?;
key.name.update(query.new_name);
self.garage.key_table.insert(&key).await?;
Ok(AdminRPC::KeyInfo(key))
}
KeyOperation::Delete(query) => {
let key = self.get_existing_key(&query.key_pattern).await?;
if !query.yes {
return Err(Error::BadRPC(format!(
"Add --yes flag to really perform this operation"
)));
}
// --- done checking, now commit ---
for (ab_name, _, _) in key.authorized_buckets.items().iter() {
if let Some(bucket) = self.garage.bucket_table.get(&EmptyKey, ab_name).await? {
if !bucket.is_deleted() {
self.update_bucket_key(bucket, &key.key_id, false, false)
.await?;
}
} else {
return Err(Error::Message(format!("Bucket not found: {}", ab_name)));
}
}
let del_key = Key::delete(key.key_id.to_string());
self.garage.key_table.insert(&del_key).await?;
Ok(AdminRPC::Ok(format!(
"Key {} was deleted successfully.",
key.key_id
)))
}
KeyOperation::Import(query) => {
let prev_key = self.garage.key_table.get(&EmptyKey, &query.key_id).await?;
if prev_key.is_some() {
return Err(Error::Message(format!("Key {} already exists in data store. Even if it is deleted, we can't let you create a new key with the same ID. Sorry.", query.key_id)));
}
let imported_key = Key::import(&query.key_id, &query.secret_key, &query.name);
self.garage.key_table.insert(&imported_key).await?;
Ok(AdminRPC::KeyInfo(imported_key))
}
}
}
async fn get_existing_bucket(&self, bucket: &String) -> Result<Bucket, Error> {
self.garage
.bucket_table
.get(&EmptyKey, bucket)
.await?
.filter(|b| !b.is_deleted())
.map(Ok)
.unwrap_or(Err(Error::BadRPC(format!(
"Bucket {} does not exist",
bucket
))))
}
async fn get_existing_key(&self, pattern: &str) -> Result<Key, Error> {
let candidates = self
.garage
.key_table
.get_range(
&EmptyKey,
None,
Some(KeyFilter::Matches(pattern.to_string())),
10,
)
.await?
.into_iter()
.filter(|k| !k.deleted.get())
.collect::<Vec<_>>();
if candidates.len() != 1 {
Err(Error::Message(format!(
"{} matching keys",
candidates.len()
)))
} else {
Ok(candidates.into_iter().next().unwrap())
}
}
/// Update **bucket table** to inform of the new linked key
async fn update_bucket_key(
&self,
mut bucket: Bucket,
key_id: &String,
allow_read: bool,
allow_write: bool,
) -> Result<(), Error> {
if let BucketState::Present(params) = bucket.state.get_mut() {
let ak = &mut params.authorized_keys;
let old_ak = ak.take_and_clear();
ak.merge(&old_ak.update_mutator(
key_id.to_string(),
PermissionSet {
allow_read,
allow_write,
},
));
} else {
return Err(Error::Message(format!(
"Bucket is deleted in update_bucket_key"
)));
}
self.garage.bucket_table.insert(&bucket).await?;
Ok(())
}
/// Update **key table** to inform of the new linked bucket
async fn update_key_bucket(
&self,
key: &Key,
bucket: &String,
allow_read: bool,
allow_write: bool,
) -> Result<(), Error> {
let mut key = key.clone();
let old_map = key.authorized_buckets.take_and_clear();
key.authorized_buckets.merge(&old_map.update_mutator(
bucket.clone(),
PermissionSet {
allow_read,
allow_write,
},
));
self.garage.key_table.insert(&key).await?;
Ok(())
}
async fn handle_launch_repair(self: &Arc<Self>, opt: RepairOpt) -> Result<AdminRPC, Error> {
if !opt.yes {
return Err(Error::BadRPC(format!(
"Please provide the --yes flag to initiate repair operations."
)));
}
if opt.all_nodes {
let mut opt_to_send = opt.clone();
opt_to_send.all_nodes = false;
let mut failures = vec![];
let ring = self.garage.system.ring.borrow().clone();
for node in ring.config.members.keys() {
if self
.rpc_client
.call(
*node,
AdminRPC::LaunchRepair(opt_to_send.clone()),
ADMIN_RPC_TIMEOUT,
)
.await
.is_err()
{
failures.push(node.clone());
}
}
if failures.is_empty() {
Ok(AdminRPC::Ok(format!("Repair launched on all nodes")))
} else {
Err(Error::Message(format!(
"Could not launch repair on nodes: {:?} (launched successfully on other nodes)",
failures
)))
}
} else {
let repair = Repair {
garage: self.garage.clone(),
};
self.garage
.system
.background
.spawn_worker("Repair worker".into(), move |must_exit| async move {
repair.repair_worker(opt, must_exit).await
});
Ok(AdminRPC::Ok(format!(
"Repair launched on {:?}",
self.garage.system.id
)))
}
}
async fn handle_stats(&self, opt: StatsOpt) -> Result<AdminRPC, Error> {
if opt.all_nodes {
let mut ret = String::new();
let ring = self.garage.system.ring.borrow().clone();
for node in ring.config.members.keys() {
let mut opt = opt.clone();
opt.all_nodes = false;
writeln!(&mut ret, "\n======================").unwrap();
writeln!(&mut ret, "Stats for node {:?}:", node).unwrap();
match self
.rpc_client
.call(*node, AdminRPC::Stats(opt), ADMIN_RPC_TIMEOUT)
.await
{
Ok(AdminRPC::Ok(s)) => writeln!(&mut ret, "{}", s).unwrap(),
Ok(x) => writeln!(&mut ret, "Bad answer: {:?}", x).unwrap(),
Err(e) => writeln!(&mut ret, "Error: {}", e).unwrap(),
}
}
Ok(AdminRPC::Ok(ret))
} else {
Ok(AdminRPC::Ok(self.gather_stats_local(opt)?))
}
}
fn gather_stats_local(&self, opt: StatsOpt) -> Result<String, Error> {
let mut ret = String::new();
writeln!(
&mut ret,
"\nGarage version: {}",
git_version::git_version!()
)
.unwrap();
// Gather ring statistics
let ring = self.garage.system.ring.borrow().clone();
let mut ring_nodes = HashMap::new();
for r in ring.ring.iter() {
for n in r.nodes.iter() {
if !ring_nodes.contains_key(n) {
ring_nodes.insert(*n, 0usize);
}
*ring_nodes.get_mut(n).unwrap() += 1;
}
}
writeln!(&mut ret, "\nRing nodes & partition count:").unwrap();
for (n, c) in ring_nodes.iter() {
writeln!(&mut ret, " {:?} {}", n, c).unwrap();
}
self.gather_table_stats(&mut ret, &self.garage.bucket_table, &opt)?;
self.gather_table_stats(&mut ret, &self.garage.key_table, &opt)?;
self.gather_table_stats(&mut ret, &self.garage.object_table, &opt)?;
self.gather_table_stats(&mut ret, &self.garage.version_table, &opt)?;
self.gather_table_stats(&mut ret, &self.garage.block_ref_table, &opt)?;
writeln!(&mut ret, "\nBlock manager stats:").unwrap();
if opt.detailed {
writeln!(
&mut ret,
" number of blocks: {}",
self.garage.block_manager.rc_len()
)
.unwrap();
}
writeln!(
&mut ret,
" resync queue length: {}",
self.garage.block_manager.resync_queue_len()
)
.unwrap();
Ok(ret)
}
fn gather_table_stats<F, R>(
&self,
to: &mut String,
t: &Arc<Table<F, R>>,
opt: &StatsOpt,
) -> Result<(), Error>
where
F: TableSchema + 'static,
R: TableReplication + 'static,
{
writeln!(to, "\nTable stats for {}", t.data.name).unwrap();
if opt.detailed {
writeln!(to, " number of items: {}", t.data.store.len()).unwrap();
writeln!(
to,
" Merkle tree size: {}",
t.merkle_updater.merkle_tree_len()
)
.unwrap();
}
writeln!(
to,
" Merkle updater todo queue length: {}",
t.merkle_updater.todo_len()
)
.unwrap();
writeln!(to, " GC todo queue length: {}", t.data.gc_todo_len()).unwrap();
Ok(())
}
}