49.2. Logical Decoding Concepts #

49.2.1. Logical Decoding
49.2.2. Replication Slots
49.2.3. Output Plugins
49.2.4. Exported Snapshots

49.2.1. Logical Decoding #

Logical decoding is the process of extracting all persistent changes to a database's tables into a coherent, easy to understand format which can be interpreted without detailed knowledge of the database's internal state.

In PostgreSQL, logical decoding is implemented by decoding the contents of the write-ahead log, which describe changes on a storage level, into an application-specific form such as a stream of tuples or SQL statements.

49.2.2. Replication Slots #

In the context of logical replication, a slot represents a stream of changes that can be replayed to a client in the order they were made on the origin server. Each slot streams a sequence of changes from a single database.

Note

PostgreSQL also has streaming replication slots (see Section 27.2.5), but they are used somewhat differently there.

A replication slot has an identifier that is unique across all databases in a PostgreSQL cluster. Slots persist independently of the connection using them and are crash-safe.

A logical slot will emit each change just once in normal operation. The current position of each slot is persisted only at checkpoint, so in the case of a crash the slot may return to an earlier LSN, which will then cause recent changes to be sent again when the server restarts. Logical decoding clients are responsible for avoiding ill effects from handling the same message more than once. Clients may wish to record the last LSN they saw when decoding and skip over any repeated data or (when using the replication protocol) request that decoding start from that LSN rather than letting the server determine the start point. The Replication Progress Tracking feature is designed for this purpose, refer to replication origins.

Multiple independent slots may exist for a single database. Each slot has its own state, allowing different consumers to receive changes from different points in the database change stream. For most applications, a separate slot will be required for each consumer.

A logical replication slot knows nothing about the state of the receiver(s). It's even possible to have multiple different receivers using the same slot at different times; they'll just get the changes following on from when the last receiver stopped consuming them. Only one receiver may consume changes from a slot at any given time.

A logical replication slot can also be created on a hot standby. To prevent VACUUM from removing required rows from the system catalogs, hot_standby_feedback should be set on the standby. In spite of that, if any required rows get removed, the slot gets invalidated. It's highly recommended to use a physical slot between the primary and the standby. Otherwise, hot_standby_feedback will work but only while the connection is alive (for example a node restart would break it). Then, the primary may delete system catalog rows that could be needed by the logical decoding on the standby (as it does not know about the catalog_xmin on the standby). Existing logical slots on standby also get invalidated if wal_level on the primary is reduced to less than logical. This is done as soon as the standby detects such a change in the WAL stream. It means that, for walsenders which are lagging (if any), some WAL records up to the wal_level parameter change on the primary won't be decoded.

Creation of a logical slot requires information about all the currently running transactions. On the primary, this information is available directly, but on a standby, this information has to be obtained from primary. Thus, slot creation may need to wait for some activity to happen on the primary. If the primary is idle, creating a logical slot on standby may take noticeable time. This can be sped up by calling the pg_log_standby_snapshot function on the primary.

Caution

Replication slots persist across crashes and know nothing about the state of their consumer(s). They will prevent removal of required resources even when there is no connection using them. This consumes storage because neither required WAL nor required rows from the system catalogs can be removed by VACUUM as long as they are required by a replication slot. In extreme cases this could cause the database to shut down to prevent transaction ID wraparound (see Section 25.1.5). So if a slot is no longer required it should be dropped.

49.2.3. Output Plugins #

Output plugins transform the data from the write-ahead log's internal representation into the format the consumer of a replication slot desires.

49.2.4. Exported Snapshots #

When a new replication slot is created using the streaming replication interface (see CREATE_REPLICATION_SLOT), a snapshot is exported (see Section 9.27.5), which will show exactly the state of the database after which all changes will be included in the change stream. This can be used to create a new replica by using SET TRANSACTION SNAPSHOT to read the state of the database at the moment the slot was created. This transaction can then be used to dump the database's state at that point in time, which afterwards can be updated using the slot's contents without losing any changes.

Creation of a snapshot is not always possible. In particular, it will fail when connected to a hot standby. Applications that do not require snapshot export may suppress it with the NOEXPORT_SNAPSHOT option.