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144 lines
7.1 KiB
Markdown
144 lines
7.1 KiB
Markdown
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title = "Internals"
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weight = 20
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## Overview
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TODO: write this section
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- The Dynamo ring (see [this paper](https://dl.acm.org/doi/abs/10.1145/1323293.1294281) and [that paper](https://www.usenix.org/conference/nsdi16/technical-sessions/presentation/eisenbud))
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- CRDTs (see [this paper](https://link.springer.com/chapter/10.1007/978-3-642-24550-3_29))
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- Consistency model of Garage tables
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In the meantime, you can find some information at the following links:
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- [this presentation (in French)](https://git.deuxfleurs.fr/Deuxfleurs/garage/src/branch/main/doc/talks/2020-12-02_wide-team/talk.pdf)
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- [an old design draft](@/documentation/working-documents/design-draft.md)
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## Request routing logic
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Data retrieval requests to Garage endpoints (S3 API and websites) are resolved
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to an individual object in a bucket. Since objects are replicated to multiple nodes
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Garage must ensure consistency before answering the request.
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### Using quorum to ensure consistency
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Garage ensures consistency by attempting to establish a quorum with the
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data nodes responsible for the object. When a majority of the data nodes
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have provided metadata on a object Garage can then answer the request.
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When a request arrives Garage will, assuming the recommended 3 replicas, perform the following actions:
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- Make a request to the two preferred nodes for object metadata
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- Try the third node if one of the two initial requests fail
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- Check that the metadata from at least 2 nodes match
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- Check that the object hasn't been marked deleted
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- Answer the request with inline data from metadata if object is small enough
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- Or get data blocks from the preferred nodes and answer using the assembled object
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Garage dynamically determines which nodes to query based on health, preference, and
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which nodes actually host a given data. Garage has no concept of "primary" so any
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healthy node with the data can be used as long as a quorum is reached for the metadata.
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### Node health
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Garage keeps a TCP session open to each node in the cluster and periodically pings them. If a connection
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cannot be established, or a node fails to answer a number of pings, the target node is marked as failed.
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Failed nodes are not used for quorum or other internal requests.
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### Node preference
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Garage prioritizes which nodes to query according to a few criteria:
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- A node always prefers itself if it can answer the request
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- Then the node prioritizes nodes in the same zone
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- Finally the nodes with the lowest latency are prioritized
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For further reading on the cluster structure look at the [gateway](@/documentation/cookbook/gateways.md)
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and [cluster layout management](@/documentation/operations/layout.md) pages.
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## Garbage collection
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A faulty garbage collection procedure has been the cause of
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[critical bug #39](https://git.deuxfleurs.fr/Deuxfleurs/garage/issues/39).
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This precise bug was fixed in the code, however there are potentially more
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general issues with the garbage collector being too eager and deleting things
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too early. This has been the subject of
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[PR #135](https://git.deuxfleurs.fr/Deuxfleurs/garage/pulls/135).
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This section summarizes the discussions on this topic.
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Rationale: we want to ensure Garage's safety by making sure things don't get
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deleted from disk if they are still needed. Two aspects are involved in this.
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### 1. Garbage collection of table entries (in `meta/` directory)
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The `Entry` trait used for table entries (defined in `tables/schema.rs`)
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defines a function `is_tombstone()` that returns `true` if that entry
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represents an entry that is deleted in the table. CRDT semantics by default
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keep all tombstones, because they are necessary for reconciliation: if node A
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has a tombstone that supersedes a value `x`, and node B has value `x`, A has to
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keep the tombstone in memory so that the value `x` can be properly deleted at
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node `B`. Otherwise, due to the CRDT reconciliation rule, the value `x` from B
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would flow back to A and a deleted item would reappear in the system.
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Here, we have some control on the nodes involved in storing Garage data.
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Therefore we have a garbage collector that is able to delete tombstones UNDER
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CERTAIN CONDITIONS. This garbage collector is implemented in `table/gc.rs`. To
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delete a tombstone, the following condition has to be met:
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- All nodes responsible for storing this entry are aware of the existence of
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the tombstone, i.e. they cannot hold another version of the entry that is
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superseeded by the tombstone. This ensures that deleting the tombstone is
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safe and that no deleted value will come back in the system.
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Garage makes use of Sled's atomic operations (such as compare-and-swap and
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transactions) to ensure that only tombstones that have been correctly
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propagated to other nodes are ever deleted from the local entry tree.
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This GC is safe in the following sense: no non-tombstone data is ever deleted
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from Garage tables.
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**However**, there is an issue with the way this interacts with data
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rebalancing in the case when a partition is moving between nodes. If a node has
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some data of a partition for which it is not responsible, it has to offload it.
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However that offload process takes some time. In that interval, the GC does not
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check with that node if it has the tombstone before deleting the tombstone, so
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perhaps it doesn't have it and when the offload finally happens, old data comes
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back in the system.
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**PR 135 mostly fixes this** by implementing a 24-hour delay before anything is
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garbage collected in a table. This works under the assumption that rebalances
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that follow data shuffling terminate in less than 24 hours.
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**However**, in distributed systems, it is generally considered a bad practice
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to make assumptions that information propagates in a certain time interval:
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this consists in making a synchrony assumption, meaning that we are basically
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assuming a computing model that has much stronger properties than otherwise. To
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maximize the applicability of Garage, we would like to remove this assumption,
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and implement a system where time does not play a role. To do this, we would
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need to find a way to safely disable the GC when data is being shuffled around,
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and safely detect that the shuffling has terminated and thus the GC can be
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resumed. This introduces some complexity to the protocol and hasn't been
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tackled yet.
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### 2. Garbage collection of data blocks (in `data/` directory)
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Blocks in the data directory are reference-counted. In Garage versions before
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PR #135, blocks could get deleted from local disk as soon as their reference
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counter reached zero. We had a mechanism to not trigger this immediately at the
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rc-reaches-zero event, but the cleanup could be triggered by other means (for
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example by a block repair operation...). PR #135 added a safety measure so that
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blocks never get deleted in a 10 minute interval following the time when the RC
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reaches zero. This is a measure to make impossible race conditions such as #39.
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We would have liked to use a larger delay (e.g. 24 hours), but in the case of a
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rebalance of data, this would have led to the disk utilization to explode
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during the rebalancing, only to shrink again after 24 hours. The 10-minute
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delay is a compromise that gives good security while not having this problem of
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disk space explosion on rebalance.
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