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Read Concern "majority"

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  • Performance
  • Availability
  • Example
  • Storage Engine Support
  • Read Concern "majority" and Transactions
  • Read Concern "majority" and Aggregation
  • Read Your Own Writes
  • Primary-Secondary-Arbiter Replica Sets
"majority"

For read operations not associated with multi-document transactions, read concern "majority" guarantees that the data read has been acknowledged by a majority of the replica set members. The documents read are durable and guaranteed to not roll back.

For operations in multi-document transactions, read concern "majority" provides its guarantees only if the transaction commits with write concern "majority". Otherwise, the "majority" read concern provides no guarantees about the data read in transactions.

Regardless of the read concern level, the most recent data on a node may not reflect the most recent version of the data in the system.

For more information about what happens if a primary fails, see Automatic Failover.

Each replica set member maintains, in memory, a view of the data at the majority-commit point; the majority-commit point is calculated by the primary. To fulfill read concern "majority", the node returns data from this view and is comparable in performance to other read concerns.

Read concern "majority" is available for use with or without causally consistent sessions and transactions.

Warning

If you are using a three-member primary-secondary-arbiter (PSA) architecture, consider the following:

  • The write concern "majority" can cause performance issues if a secondary is unavailable or lagging. For advice on how to mitigate these issues, see Mitigate Performance Issues with a Self-Managed PSA Replica Set.

  • If you are using a global default "majority" and the write concern is less than the size of the majority, your queries may return stale (not fully replicated) data.

Consider the following timeline of a write operation Write 0 to a three member replica set:

Note

For simplification, the example assumes:

  • All writes prior to Write 0 have been successfully replicated to all members.

  • Write prev is the previous write before Write 0.

  • No other writes have occured after Write 0.

Timeline of a write operation to a three member replica set
Time
Event
Most Recent Write
Most Recent w: "majority" write

t 0

Primary applies Write 0

Primary: Write 0
Secondary 1: Write prev
Secondary 2: Write prev
Primary: Write prev
Secondary 1: Write prev
Secondary 2: Write prev

t 1

Secondary 1 applies write 0

Primary: Write 0
Secondary 1: Write 0
Secondary 2: Write prev
Primary: Write prev
Secondary 1: Write prev
Secondary 2: Write prev

t 2

Secondary 2 applies write 0

Primary: Write 0
Secondary 1: Write 0
Secondary 2: Write 0
Primary: Write prev
Secondary 1: Write prev
Secondary 2: Write prev

t 3

Primary is aware of successful replication to Secondary 1 and sends acknowledgement to client

Primary: Write 0
Secondary 1: Write 0
Secondary 2: Write 0
Primary: Write 0
Secondary 1: Write prev
Secondary 2: Write prev

t 4

Primary is aware of successful replication to Secondary 2

Primary: Write 0
Secondary 1: Write 0
Secondary 2: Write 0
Primary: Write 0
Secondary 1: Write prev
Secondary 2: Write prev

t 5

Secondary 1 receives notice (through regular replication mechanism) to update its snapshot of its most recent w: "majority" write

Primary: Write 0
Secondary 1: Write 0
Secondary 2: Write 0
Primary: Write 0
Secondary 1: Write 0
Secondary 2: Write prev

t 6

Secondary 2 receives notice (through regular replication mechanism) to update its snapshot of its most recent w: "majority" write

Primary: Write 0
Secondary 1: Write 0
Secondary 2: Write 0
Primary: Write 0
Secondary 1: Write 0
Secondary 2: Write 0

Then, the following tables summarizes the state of the data that a read operation with "majority" read concern would see at time T.

Timeline of a write operation to a three member replica set.
Read Target
Time T
State of Data

Primary

Before t 3

Data reflects Write prev

Primary

After t 3

Data reflects Write 0

Secondary 1

Before t 5

Data reflects Write prev

Secondary 1

After t 5

Data reflects Write 0

Secondary 2

Before or at t 6

Data reflects Write prev

Secondary 2

After t 6

Data reflects Write 0

Read concern "majority" is available for the WiredTiger storage engine.

Tip

The serverStatus command returns the storageEngine.supportsCommittedReads field, which indicates whether the storage engine supports "majority" read concern.

Note

You set the read concern at the transaction level, not at the individual operation level. To set the read concern for transactions, see Transactions and Read Concern.

For operations in multi-document transactions, read concern "majority" provides its guarantees only if the transaction commits with write concern "majority". Otherwise, the "majority" read concern provides no guarantees about the data read in transactions.

You can specify read concern level "majority" for an aggregation that includes an $out stage.

You can use causally consistent sessions to read your own writes, if the writes request acknowledgment.

Starting in MongoDB 5.0, enableMajorityReadConcern and --enableMajorityReadConcern cannot be changed and are always set to true due to storage engine improvements.

In earlier versions of MongoDB, enableMajorityReadConcern and --enableMajorityReadConcern are configurable and can be set to false to prevent storage cache pressure from immobilizing a deployment with a three-member primary-secondary-arbiter (PSA) architecture.

If you are using a three-member primary-secondary-arbiter (PSA) architecture, consider the following:

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