forked from Deuxfleurs/garage
[fix-buffering] implement block_ram_buffer_max
to avoid excessive RAM usage
This commit is contained in:
parent
95eb8808e8
commit
0d3e285d13
7 changed files with 148 additions and 13 deletions
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@ -20,6 +20,7 @@ metadata_auto_snapshot_interval = "6h"
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db_engine = "lmdb"
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block_size = "1M"
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block_ram_buffer_max = "256MiB"
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sled_cache_capacity = "128MiB"
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sled_flush_every_ms = 2000
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@ -88,6 +89,7 @@ The following gives details about each available configuration option.
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Top-level configuration options:
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[`allow_world_readable_secrets`](#allow_world_readable_secrets),
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[`block_ram_buffer_max`](#block_ram_buffer_max),
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[`block_size`](#block_size),
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[`bootstrap_peers`](#bootstrap_peers),
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[`compression_level`](#compression_level),
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@ -420,6 +422,37 @@ files will remain available. This however means that chunks from existing files
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will not be deduplicated with chunks from newly uploaded files, meaning you
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might use more storage space that is optimally possible.
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#### `block_ram_buffer_max` (since v0.9.4) {#block_ram_buffer_max}
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A limit on the total size of data blocks kept in RAM by S3 API nodes awaiting
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to be sent to storage nodes asynchronously.
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Explanation: since Garage wants to tolerate node failures, it uses quorum
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writes to send data blocks to storage nodes: try to write the block to three
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nodes, and return ok as soon as two writes complete. So even if all three nodes
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are online, the third write always completes asynchronously. In general, there
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are not many writes to a cluster, and the third asynchronous write can
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terminate early enough so as to not cause unbounded RAM growth. However, if
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the S3 API node is continuously receiving large quantities of data and the
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third node is never able to catch up, many data blocks will be kept buffered in
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RAM as they are awaiting transfer to the third node.
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The `block_ram_buffer_max` sets a limit to the size of buffers that can be kept
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in RAM in this process. When the limit is reached, backpressure is applied
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back to the S3 client.
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Note that this only counts buffers that have arrived to a certain stage of
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processing (received from the client + encrypted and/or compressed as
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necessary) and are ready to send to the storage nodes. Many other buffers will
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not be counted and this is not a hard limit on RAM consumption. In particular,
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if many clients send requests simultaneously with large objects, the RAM
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consumption will always grow linearly with the number of concurrent requests,
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as each request will use a few buffers of size `block_size` for receiving and
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intermediate processing before even trying to send the data to the storage
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node.
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The default value is 256MiB.
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#### `sled_cache_capacity` {#sled_cache_capacity}
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This parameter can be used to tune the capacity of the cache used by
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@ -225,6 +225,17 @@ block_bytes_read 120586322022
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block_bytes_written 3386618077
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```
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#### `block_ram_buffer_free_kb` (gauge)
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Kibibytes available for buffering blocks that have to be sent to remote nodes.
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When clients send too much data to this node and a storage node is not receiving
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data fast enough due to slower network conditions, this will decrease down to
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zero and backpressure will be applied.
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```
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block_ram_buffer_free_kb 219829
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```
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#### `block_compression_level` (counter)
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Exposes the block compression level configured for the Garage node.
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@ -1,3 +1,4 @@
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use std::convert::TryInto;
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use std::path::PathBuf;
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use std::sync::Arc;
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use std::time::Duration;
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@ -10,7 +11,7 @@ use serde::{Deserialize, Serialize};
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use tokio::fs;
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use tokio::io::{AsyncReadExt, AsyncWriteExt, BufReader};
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use tokio::sync::{mpsc, Mutex, MutexGuard};
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use tokio::sync::{mpsc, Mutex, MutexGuard, Semaphore};
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use opentelemetry::{
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trace::{FutureExt as OtelFutureExt, TraceContextExt, Tracer},
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@ -93,6 +94,7 @@ pub struct BlockManager {
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pub(crate) system: Arc<System>,
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pub(crate) endpoint: Arc<Endpoint<BlockRpc, Self>>,
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buffer_kb_semaphore: Arc<Semaphore>,
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pub(crate) metrics: BlockManagerMetrics,
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@ -152,11 +154,14 @@ impl BlockManager {
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.netapp
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.endpoint("garage_block/manager.rs/Rpc".to_string());
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let buffer_kb_semaphore = Arc::new(Semaphore::new(config.block_ram_buffer_max / 1024));
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let metrics = BlockManagerMetrics::new(
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config.compression_level,
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rc.rc.clone(),
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resync.queue.clone(),
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resync.errors.clone(),
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buffer_kb_semaphore.clone(),
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);
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let scrub_persister = PersisterShared::new(&system.metadata_dir, "scrub_info");
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@ -176,6 +181,7 @@ impl BlockManager {
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resync,
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system,
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endpoint,
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buffer_kb_semaphore,
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metrics,
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scrub_persister,
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tx_scrub_command: ArcSwapOption::new(None),
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@ -361,6 +367,14 @@ impl BlockManager {
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let (header, bytes) = DataBlock::from_buffer(data, self.compression_level)
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.await
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.into_parts();
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let permit = self
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.buffer_kb_semaphore
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.clone()
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.acquire_many_owned((bytes.len() / 1024).try_into().unwrap())
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.await
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.ok_or_message("could not reserve space for buffer of data to send to remote nodes")?;
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let put_block_rpc =
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Req::new(BlockRpc::PutBlock { hash, header })?.with_stream_from_buffer(bytes);
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let put_block_rpc = if let Some(tag) = order_tag {
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@ -376,6 +390,7 @@ impl BlockManager {
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&who[..],
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put_block_rpc,
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RequestStrategy::with_priority(PRIO_NORMAL | PRIO_SECONDARY)
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.with_drop_on_completion(permit)
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.with_quorum(self.replication.write_quorum()),
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)
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.await?;
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@ -1,3 +1,7 @@
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use std::sync::Arc;
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use tokio::sync::Semaphore;
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use opentelemetry::{global, metrics::*};
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use garage_db as db;
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@ -9,6 +13,7 @@ pub struct BlockManagerMetrics {
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pub(crate) _rc_size: ValueObserver<u64>,
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pub(crate) _resync_queue_len: ValueObserver<u64>,
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pub(crate) _resync_errored_blocks: ValueObserver<u64>,
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pub(crate) _buffer_free_kb: ValueObserver<u64>,
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pub(crate) resync_counter: BoundCounter<u64>,
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pub(crate) resync_error_counter: BoundCounter<u64>,
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@ -31,6 +36,7 @@ impl BlockManagerMetrics {
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rc_tree: db::Tree,
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resync_queue: CountedTree,
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resync_errors: CountedTree,
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buffer_semaphore: Arc<Semaphore>,
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) -> Self {
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let meter = global::meter("garage_model/block");
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Self {
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@ -66,6 +72,15 @@ impl BlockManagerMetrics {
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.with_description("Number of block hashes whose last resync resulted in an error")
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.init(),
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_buffer_free_kb: meter
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.u64_value_observer("block.ram_buffer_free_kb", move |observer| {
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observer.observe(buffer_semaphore.available_permits() as u64, &[])
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})
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.with_description(
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"Available RAM in KiB to use for buffering data blocks to be written to remote nodes",
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)
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.init(),
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resync_counter: meter
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.u64_counter("block.resync_counter")
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.with_description("Number of calls to resync_block")
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@ -300,7 +300,11 @@ impl K2VRpcHandler {
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let rs = RequestStrategy::with_priority(PRIO_NORMAL).without_timeout();
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let mut requests = nodes
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.iter()
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.map(|node| self.system.rpc.call(&self.endpoint, *node, msg.clone(), rs))
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.map(|node| {
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self.system
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.rpc
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.call(&self.endpoint, *node, msg.clone(), rs.clone())
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})
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.collect::<FuturesUnordered<_>>();
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// Fetch responses. This procedure stops fetching responses when any of the following
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@ -33,8 +33,7 @@ use crate::ring::Ring;
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const DEFAULT_TIMEOUT: Duration = Duration::from_secs(300);
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/// Strategy to apply when making RPC
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#[derive(Copy, Clone)]
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pub struct RequestStrategy {
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pub struct RequestStrategy<T> {
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/// Min number of response to consider the request successful
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pub rs_quorum: Option<usize>,
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/// Should requests be dropped after enough response are received
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@ -43,6 +42,8 @@ pub struct RequestStrategy {
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pub rs_priority: RequestPriority,
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/// Custom timeout for this request
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rs_timeout: Timeout,
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/// Data to drop when everything completes
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rs_drop_on_complete: T,
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}
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#[derive(Copy, Clone)]
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@ -52,7 +53,19 @@ enum Timeout {
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Custom(Duration),
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}
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impl RequestStrategy {
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impl Clone for RequestStrategy<()> {
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fn clone(&self) -> Self {
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RequestStrategy {
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rs_quorum: self.rs_quorum,
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rs_interrupt_after_quorum: self.rs_interrupt_after_quorum,
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rs_priority: self.rs_priority,
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rs_timeout: self.rs_timeout,
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rs_drop_on_complete: (),
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}
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}
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}
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impl RequestStrategy<()> {
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/// Create a RequestStrategy with default timeout and not interrupting when quorum reached
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pub fn with_priority(prio: RequestPriority) -> Self {
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RequestStrategy {
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@ -60,8 +73,22 @@ impl RequestStrategy {
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rs_interrupt_after_quorum: false,
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rs_priority: prio,
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rs_timeout: Timeout::Default,
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rs_drop_on_complete: (),
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}
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}
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/// Add an item to be dropped on completion
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pub fn with_drop_on_completion<T>(self, drop_on_complete: T) -> RequestStrategy<T> {
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RequestStrategy {
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rs_quorum: self.rs_quorum,
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rs_interrupt_after_quorum: self.rs_interrupt_after_quorum,
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rs_priority: self.rs_priority,
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rs_timeout: self.rs_timeout,
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rs_drop_on_complete: drop_on_complete,
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}
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}
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}
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impl<T> RequestStrategy<T> {
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/// Set quorum to be reached for request
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pub fn with_quorum(mut self, quorum: usize) -> Self {
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self.rs_quorum = Some(quorum);
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@ -83,6 +110,19 @@ impl RequestStrategy {
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self.rs_timeout = Timeout::Custom(timeout);
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self
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}
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/// Extract drop_on_complete item
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fn extract_drop_on_complete(self) -> (RequestStrategy<()>, T) {
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(
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RequestStrategy {
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rs_quorum: self.rs_quorum,
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rs_interrupt_after_quorum: self.rs_interrupt_after_quorum,
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rs_priority: self.rs_priority,
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rs_timeout: self.rs_timeout,
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rs_drop_on_complete: (),
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},
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self.rs_drop_on_complete,
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)
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}
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}
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#[derive(Clone)]
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@ -123,7 +163,7 @@ impl RpcHelper {
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endpoint: &Endpoint<M, H>,
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to: Uuid,
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msg: N,
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strat: RequestStrategy,
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strat: RequestStrategy<()>,
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) -> Result<S, Error>
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where
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M: Rpc<Response = Result<S, Error>>,
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@ -176,7 +216,7 @@ impl RpcHelper {
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endpoint: &Endpoint<M, H>,
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to: &[Uuid],
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msg: N,
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strat: RequestStrategy,
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strat: RequestStrategy<()>,
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) -> Result<Vec<(Uuid, Result<S, Error>)>, Error>
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where
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M: Rpc<Response = Result<S, Error>>,
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@ -187,7 +227,7 @@ impl RpcHelper {
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let resps = join_all(
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to.iter()
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.map(|to| self.call(endpoint, *to, msg.clone(), strat)),
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.map(|to| self.call(endpoint, *to, msg.clone(), strat.clone())),
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)
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.await;
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Ok(to
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@ -201,7 +241,7 @@ impl RpcHelper {
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&self,
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endpoint: &Endpoint<M, H>,
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msg: N,
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strat: RequestStrategy,
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strat: RequestStrategy<()>,
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) -> Result<Vec<(Uuid, Result<S, Error>)>, Error>
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where
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M: Rpc<Response = Result<S, Error>>,
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@ -220,18 +260,19 @@ impl RpcHelper {
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/// Make a RPC call to multiple servers, returning either a Vec of responses,
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/// or an error if quorum could not be reached due to too many errors
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pub async fn try_call_many<M, N, H, S>(
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pub async fn try_call_many<M, N, H, S, T>(
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&self,
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endpoint: &Arc<Endpoint<M, H>>,
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to: &[Uuid],
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msg: N,
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strategy: RequestStrategy,
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strategy: RequestStrategy<T>,
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) -> Result<Vec<S>, Error>
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where
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M: Rpc<Response = Result<S, Error>> + 'static,
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N: IntoReq<M>,
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H: StreamingEndpointHandler<M> + 'static,
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S: Send + 'static,
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T: Send + 'static,
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{
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let quorum = strategy.rs_quorum.unwrap_or(to.len());
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@ -260,12 +301,12 @@ impl RpcHelper {
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.await
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}
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async fn try_call_many_internal<M, N, H, S>(
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async fn try_call_many_internal<M, N, H, S, T>(
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&self,
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endpoint: &Arc<Endpoint<M, H>>,
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to: &[Uuid],
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msg: N,
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strategy: RequestStrategy,
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strategy: RequestStrategy<T>,
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quorum: usize,
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) -> Result<Vec<S>, Error>
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where
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@ -273,9 +314,12 @@ impl RpcHelper {
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N: IntoReq<M>,
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H: StreamingEndpointHandler<M> + 'static,
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S: Send + 'static,
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T: Send + 'static,
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{
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let msg = msg.into_req().map_err(garage_net::error::Error::from)?;
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let (strategy, drop_on_complete) = strategy.extract_drop_on_complete();
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// Build future for each request
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// They are not started now: they are added below in a FuturesUnordered
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// object that will take care of polling them (see below)
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@ -283,6 +327,7 @@ impl RpcHelper {
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let self2 = self.clone();
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let msg = msg.clone();
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let endpoint2 = endpoint.clone();
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let strategy = strategy.clone();
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(to, async move {
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self2.call(&endpoint2, to, msg, strategy).await
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})
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@ -377,6 +422,7 @@ impl RpcHelper {
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// they have to be put in a proper queue that is persisted to disk.
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tokio::spawn(async move {
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resp_stream.collect::<Vec<Result<_, _>>>().await;
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drop(drop_on_complete);
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});
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}
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}
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@ -52,6 +52,14 @@ pub struct Config {
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)]
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pub compression_level: Option<i32>,
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/// Maximum amount of block data to buffer in RAM for sending to
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/// remote nodes when these nodes are on slower links
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#[serde(
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deserialize_with = "deserialize_capacity",
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default = "default_block_ram_buffer_max"
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)]
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pub block_ram_buffer_max: usize,
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/// Skip the permission check of secret files. Useful when
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/// POSIX ACLs (or more complex chmods) are used.
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#[serde(default)]
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@ -255,6 +263,9 @@ fn default_sled_flush_every_ms() -> u64 {
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fn default_block_size() -> usize {
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1048576
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}
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fn default_block_ram_buffer_max() -> usize {
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256 * 1024 * 1024
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}
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fn default_compression() -> Option<i32> {
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Some(1)
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