212 lines
9.8 KiB
Plaintext
212 lines
9.8 KiB
Plaintext
---
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layout: docs
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page_title: Consensus Protocol
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description: |-
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Nomad uses a consensus protocol to provide Consistency as defined by CAP.
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The consensus protocol is based on Raft: In search of an Understandable
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Consensus Algorithm. For a visual explanation of Raft, see The Secret Lives of
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Data.
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---
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# Consensus Protocol
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Nomad uses a [consensus protocol](<https://en.wikipedia.org/wiki/Consensus_(computer_science)>)
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to provide [Consistency (as defined by CAP)](https://en.wikipedia.org/wiki/CAP_theorem).
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The consensus protocol is based on
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["Raft: In search of an Understandable Consensus Algorithm"](https://raft.github.io/raft.pdf).
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For a visual explanation of Raft, see [The Secret Lives of Data](http://thesecretlivesofdata.com/raft).
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~> **Advanced Topic!** This page covers technical details of
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the internals of Nomad. You do not need to know these details to effectively
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operate and use Nomad. These details are documented here for those who wish
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to learn about them without having to go spelunking through the source code.
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## Raft Protocol Overview
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Raft is a consensus algorithm that is based on
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[Paxos](https://en.wikipedia.org/wiki/Paxos_%28computer_science%29). Compared
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to Paxos, Raft is designed to have fewer states and a simpler, more
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understandable algorithm.
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There are a few key terms to know when discussing Raft:
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- **Log** - The primary unit of work in a Raft system is a log entry. The problem
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of consistency can be decomposed into a _replicated log_. A log is an ordered
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sequence of entries. We consider the log consistent if all members agree on
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the entries and their order.
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- **FSM** - [Finite State Machine](https://en.wikipedia.org/wiki/Finite-state_machine).
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An FSM is a collection of finite states with transitions between them. As new logs
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are applied, the FSM is allowed to transition between states. Application of the
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same sequence of logs must result in the same state, meaning behavior must be deterministic.
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- **Peer set** - The peer set is the set of all members participating in log replication.
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For Nomad's purposes, all server nodes are in the peer set of the local region.
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- **Quorum** - A quorum is a majority of members from a peer set: for a set of size `n`,
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quorum requires at least `⌊(n/2)+1⌋` members.
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For example, if there are 5 members in the peer set, we would need 3 nodes
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to form a quorum. If a quorum of nodes is unavailable for any reason, the
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cluster becomes _unavailable_ and no new logs can be committed.
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- **Committed Entry** - An entry is considered _committed_ when it is durably stored
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on a quorum of nodes. Once an entry is committed it can be applied.
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- **Leader** - At any given time, the peer set elects a single node to be the leader.
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The leader is responsible for ingesting new log entries, replicating to followers,
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and managing when an entry is considered committed.
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Raft is a complex protocol and will not be covered here in detail (for those who
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desire a more comprehensive treatment, the full specification is available in this
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[paper](https://raft.github.io/raft.pdf)).
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We will, however, attempt to provide a high level description which may be useful
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for building a mental model.
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Raft nodes are always in one of three states: follower, candidate, or leader. All
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nodes initially start out as a follower. In this state, nodes can accept log entries
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from a leader and cast votes. If no entries are received for some time, nodes
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self-promote to the candidate state. In the candidate state, nodes request votes from
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their peers. If a candidate receives a quorum of votes, then it is promoted to a leader.
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The leader must accept new log entries and replicate to all the other followers.
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In addition, if stale reads are not acceptable, all queries must also be performed on
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the leader.
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Once a cluster has a leader, it is able to accept new log entries. A client can
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request that a leader append a new log entry (from Raft's perspective, a log entry
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is an opaque binary blob). The leader then writes the entry to durable storage and
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attempts to replicate to a quorum of followers. Once the log entry is considered
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_committed_, it can be _applied_ to a finite state machine. The finite state machine
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is application specific; in Nomad's case, we use
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[MemDB](https://github.com/hashicorp/go-memdb) to maintain cluster state.
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Obviously, it would be undesirable to allow a replicated log to grow in an unbounded
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fashion. Raft provides a mechanism by which the current state is snapshotted and the
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log is compacted. Because of the FSM abstraction, restoring the state of the FSM must
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result in the same state as a replay of old logs. This allows Raft to capture the FSM
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state at a point in time and then remove all the logs that were used to reach that
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state. This is performed automatically without user intervention and prevents unbounded
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disk usage while also minimizing time spent replaying logs. One of the advantages of
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using MemDB is that it allows Nomad to continue accepting new transactions even while
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old state is being snapshotted, preventing any availability issues.
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Consensus is fault-tolerant up to the point where quorum is available.
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If a quorum of nodes is unavailable, it is impossible to process log entries or reason
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about peer membership. For example, suppose there are only 2 peers: A and B. The quorum
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size is also 2, meaning both nodes must agree to commit a log entry. If either A or B
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fails, it is now impossible to reach quorum. This means the cluster is unable to add
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or remove a node or to commit any additional log entries. This results in
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_unavailability_. At this point, manual intervention would be required to remove
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either A or B and to restart the remaining node in bootstrap mode.
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A Raft cluster of 3 nodes can tolerate a single node failure while a cluster
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of 5 can tolerate 2 node failures. The recommended configuration is to either
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run 3 or 5 Nomad servers per region. This maximizes availability without
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greatly sacrificing performance. The [deployment table](#deployment_table) below
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summarizes the potential cluster size options and the fault tolerance of each.
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In terms of performance, Raft is comparable to Paxos. Assuming stable leadership,
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committing a log entry requires a single round trip to half of the cluster.
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Thus, performance is bound by disk I/O and network latency.
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## Raft in Nomad
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Only Nomad server nodes participate in Raft and are part of the peer set. All
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client nodes forward requests to servers. The clients in Nomad only need to know
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about their allocations and query that information from the servers, while the
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servers need to maintain the global state of the cluster.
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Since all servers participate as part of the peer set, they all know the current
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leader. When an RPC request arrives at a non-leader server, the request is
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forwarded to the leader. If the RPC is a _query_ type, meaning it is read-only,
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the leader generates the result based on the current state of the FSM. If
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the RPC is a _transaction_ type, meaning it modifies state, the leader
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generates a new log entry and applies it using Raft. Once the log entry is committed
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and applied to the FSM, the transaction is complete.
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Because of the nature of Raft's replication, performance is sensitive to network
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latency. For this reason, each region elects an independent leader and maintains
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a disjoint peer set. Data is partitioned by region, so each leader is responsible
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only for data in their region. When a request is received for a remote region,
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the request is forwarded to the correct leader. This design allows for lower latency
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transactions and higher availability without sacrificing consistency.
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## Consistency Modes
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Although all writes to the replicated log go through Raft, reads are more
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flexible. To support various trade-offs that developers may want, Nomad
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supports 2 different consistency modes for reads.
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The two read modes are:
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- `default` - Raft makes use of leader leasing, providing a time window
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in which the leader assumes its role is stable. However, if a leader
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is partitioned from the remaining peers, a new leader may be elected
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while the old leader is holding the lease. This means there are 2 leader
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nodes. There is no risk of a split-brain since the old leader will be
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unable to commit new logs. However, if the old leader services any reads,
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the values are potentially stale. The default consistency mode relies only
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on leader leasing, exposing clients to potentially stale values. We make
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this trade-off because reads are fast, usually strongly consistent, and
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only stale in a hard-to-trigger situation. The time window of stale reads
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is also bounded since the leader will step down due to the partition.
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- `stale` - This mode allows any server to service the read regardless of if
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it is the leader. This means reads can be arbitrarily stale but are generally
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within 50 milliseconds of the leader. The trade-off is very fast and scalable
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reads but with stale values. This mode allows reads without a leader meaning
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a cluster that is unavailable will still be able to respond.
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## Deployment Table ((#deployment_table))
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Below is a table that shows quorum size and failure tolerance for various
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cluster sizes. The recommended deployment is either 3 or 5 servers. A single
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server deployment is _**highly**_ discouraged as data loss is inevitable in a
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failure scenario.
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<table>
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<thead>
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<tr>
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<th>Servers</th>
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<th>Quorum Size</th>
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<th>Failure Tolerance</th>
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</tr>
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</thead>
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<tbody>
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<tr>
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<td>1</td>
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<td>1</td>
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<td>0</td>
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</tr>
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<tr>
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<td>2</td>
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<td>2</td>
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<td>0</td>
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</tr>
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<tr class="warning">
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<td>3</td>
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<td>2</td>
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<td>1</td>
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</tr>
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<tr>
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<td>4</td>
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<td>3</td>
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<td>1</td>
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</tr>
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<tr class="warning">
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<td>5</td>
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<td>3</td>
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<td>2</td>
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</tr>
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<tr>
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<td>6</td>
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<td>4</td>
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<td>2</td>
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</tr>
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<tr>
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<td>7</td>
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<td>4</td>
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<td>3</td>
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</tr>
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</tbody>
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</table>
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