garage/doc/book/design/internals.md
Alex Auvolat f6aebefcc9
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Some work on documentation towards v0.8
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+++ title = "Internals" weight = 20 +++

Overview

TODO: write this section

In the meantime, you can find some information at the following links:

Request routing logic

Data retrieval requests to Garage endpoints (S3 API and websites) are resolved to an individual object in a bucket. Since objects are replicated to multiple nodes Garage must ensure consistency before answering the request.

Using quorum to ensure consistency

Garage ensures consistency by attempting to establish a quorum with the data nodes responsible for the object. When a majority of the data nodes have provided metadata on a object Garage can then answer the request.

When a request arrives Garage will, assuming the recommended 3 replicas, perform the following actions:

  • Make a request to the two preferred nodes for object metadata
  • Try the third node if one of the two initial requests fail
  • Check that the metadata from at least 2 nodes match
  • Check that the object hasn't been marked deleted
  • Answer the request with inline data from metadata if object is small enough
  • Or get data blocks from the preferred nodes and answer using the assembled object

Garage dynamically determines which nodes to query based on health, preference, and which nodes actually host a given data. Garage has no concept of "primary" so any healthy node with the data can be used as long as a quorum is reached for the metadata.

Node health

Garage keeps a TCP session open to each node in the cluster and periodically pings them. If a connection cannot be established, or a node fails to answer a number of pings, the target node is marked as failed. Failed nodes are not used for quorum or other internal requests.

Node preference

Garage prioritizes which nodes to query according to a few criteria:

  • A node always prefers itself if it can answer the request
  • Then the node prioritizes nodes in the same zone
  • Finally the nodes with the lowest latency are prioritized

For further reading on the cluster structure look at the gateway and cluster layout management pages.

Garbage collection

A faulty garbage collection procedure has been the cause of critical bug #39. This precise bug was fixed in the code, however there are potentially more general issues with the garbage collector being too eager and deleting things too early. This has been the subject of PR #135. This section summarizes the discussions on this topic.

Rationale: we want to ensure Garage's safety by making sure things don't get deleted from disk if they are still needed. Two aspects are involved in this.

1. Garbage collection of table entries (in meta/ directory)

The Entry trait used for table entries (defined in tables/schema.rs) defines a function is_tombstone() that returns true if that entry represents an entry that is deleted in the table. CRDT semantics by default keep all tombstones, because they are necessary for reconciliation: if node A has a tombstone that supersedes a value x, and node B has value x, A has to keep the tombstone in memory so that the value x can be properly deleted at node B. Otherwise, due to the CRDT reconciliation rule, the value x from B would flow back to A and a deleted item would reappear in the system.

Here, we have some control on the nodes involved in storing Garage data. Therefore we have a garbage collector that is able to delete tombstones UNDER CERTAIN CONDITIONS. This garbage collector is implemented in table/gc.rs. To delete a tombstone, the following condition has to be met:

  • All nodes responsible for storing this entry are aware of the existence of the tombstone, i.e. they cannot hold another version of the entry that is superseeded by the tombstone. This ensures that deleting the tombstone is safe and that no deleted value will come back in the system.

Garage makes use of Sled's atomic operations (such as compare-and-swap and transactions) to ensure that only tombstones that have been correctly propagated to other nodes are ever deleted from the local entry tree.

This GC is safe in the following sense: no non-tombstone data is ever deleted from Garage tables.

However, there is an issue with the way this interacts with data rebalancing in the case when a partition is moving between nodes. If a node has some data of a partition for which it is not responsible, it has to offload it. However that offload process takes some time. In that interval, the GC does not check with that node if it has the tombstone before deleting the tombstone, so perhaps it doesn't have it and when the offload finally happens, old data comes back in the system.

PR 135 mostly fixes this by implementing a 24-hour delay before anything is garbage collected in a table. This works under the assumption that rebalances that follow data shuffling terminate in less than 24 hours.

However, in distributed systems, it is generally considered a bad practice to make assumptions that information propagates in a certain time interval: this consists in making a synchrony assumption, meaning that we are basically assuming a computing model that has much stronger properties than otherwise. To maximize the applicability of Garage, we would like to remove this assumption, and implement a system where time does not play a role. To do this, we would need to find a way to safely disable the GC when data is being shuffled around, and safely detect that the shuffling has terminated and thus the GC can be resumed. This introduces some complexity to the protocol and hasn't been tackled yet.

2. Garbage collection of data blocks (in data/ directory)

Blocks in the data directory are reference-counted. In Garage versions before PR #135, blocks could get deleted from local disk as soon as their reference counter reached zero. We had a mechanism to not trigger this immediately at the rc-reaches-zero event, but the cleanup could be triggered by other means (for example by a block repair operation...). PR #135 added a safety measure so that blocks never get deleted in a 10 minute interval following the time when the RC reaches zero. This is a measure to make impossible race conditions such as #39. We would have liked to use a larger delay (e.g. 24 hours), but in the case of a rebalance of data, this would have led to the disk utilization to explode during the rebalancing, only to shrink again after 24 hours. The 10-minute delay is a compromise that gives good security while not having this problem of disk space explosion on rebalance.