Debezium connector for PostgreSQL

Overview

PostgreSQL’s logical decoding feature was introduced in version 9.4. It is a mechanism that allows the extraction of the changes that were committed to the transaction log and the processing of these changes in a user-friendly manner with the help of an output plug-in. The output plug-in enables clients to consume the changes.

The PostgreSQL connector contains two main parts that work together to read and process database changes:

  • A logical decoding output plug-in. You might need to install the output plug-in that you choose to use. You must configure a replication slot that uses your chosen output plug-in before running the PostgreSQL server. The plug-in can be one of the following:

    • decoderbufs is based on Protobuf and maintained by the Debezium community.

    • pgoutput is the standard logical decoding output plug-in in PostgreSQL 10+. It is maintained by the PostgreSQL community, and used by PostgreSQL itself for logical replication. This plug-in is always present so no additional libraries need to be installed. The Debezium connector interprets the raw replication event stream directly into change events.

  • Java code (the actual Kafka Connect connector) that reads the changes produced by the chosen logical decoding output plug-in. It uses PostgreSQL’s streaming replication protocol, by means of the PostgreSQL JDBC driver

The connector produces a change event for every row-level insert, update, and delete operation that was captured and sends change event records for each table in a separate Kafka topic. Client applications read the Kafka topics that correspond to the database tables of interest, and can react to every row-level event they receive from those topics.

PostgreSQL normally purges write-ahead log (WAL) segments after some period of time. This means that the connector does not have the complete history of all changes that have been made to the database. Therefore, when the PostgreSQL connector first connects to a particular PostgreSQL database, it starts by performing a consistent snapshot of each of the database schemas. After the connector completes the snapshot, it continues streaming changes from the exact point at which the snapshot was made. This way, the connector starts with a consistent view of all of the data, and does not omit any changes that were made while the snapshot was being taken.

The connector is tolerant of failures. As the connector reads changes and produces events, it records the WAL position for each event. If the connector stops for any reason (including communication failures, network problems, or crashes), upon restart the connector continues reading the WAL where it last left off. This includes snapshots. If the connector stops during a snapshot, the connector begins a new snapshot when it restarts.

The connector relies on and reflects the PostgreSQL logical decoding feature, which has the following limitations:

  • Logical decoding does not support DDL changes. This means that the connector is unable to report DDL change events back to consumers.

  • Logical decoding replication slots are supported on only primary servers. When there is a cluster of PostgreSQL servers, the connector can run on only the active primary server. It cannot run on hot or warm standby replicas. If the primary server fails or is demoted, the connector stops. After the primary server has recovered, you can restart the connector. If a different PostgreSQL server has been promoted to primary, adjust the connector configuration before restarting the connector.

Behavior when things go wrong describes how the connector responds if there is a problem.

Debezium currently supports databases with UTF-8 character encoding only. With a single byte character encoding, it is not possible to correctly process strings that contain extended ASCII code characters.

How the connector works

To optimally configure and run a Debezium PostgreSQL connector, it is helpful to understand how the connector performs snapshots, streams change events, determines Kafka topic names, and uses metadata.

Security

To use the Debezium connector to stream changes from a PostgreSQL database, the connector must operate with specific privileges in the database. Although one way to grant the necessary privileges is to provide the user with superuser privileges, doing so potentially exposes your PostgreSQL data to unauthorized access. Rather than granting excessive privileges to the Debezium user, it is best to create a dedicated Debezium replication user to which you grant specific privileges.

For more information about configuring privileges for the Debezium PostgreSQL user, see Setting up permissions. For more information about PostgreSQL logical replication security, see the PostgreSQL documentation.

Snapshots

Most PostgreSQL servers are configured to not retain the complete history of the database in the WAL segments. This means that the PostgreSQL connector would be unable to see the entire history of the database by reading only the WAL. Consequently, the first time that the connector starts, it performs an initial consistent snapshot of the database.

Default workflow behavior of initial snapshots

The default behavior for performing a snapshot consists of the following steps. You can change this behavior by setting the snapshot.mode connector configuration property to a value other than initial.

  1. Start a transaction with a SERIALIZABLE, READ ONLY, DEFERRABLE isolation level to ensure that subsequent reads in this transaction are against a single consistent version of the data. Any changes to the data due to subsequent INSERT, UPDATE, and DELETE operations by other clients are not visible to this transaction.

  2. Read the current position in the server’s transaction log.

  3. Scan the database tables and schemas, generate a READ event for each row and write that event to the appropriate table-specific Kafka topic.

  4. Commit the transaction.

  5. Record the successful completion of the snapshot in the connector offsets.

If the connector fails, is rebalanced, or stops after Step 1 begins but before Step 5 completes, upon restart the connector begins a new snapshot. After the connector completes its initial snapshot, the PostgreSQL connector continues streaming from the position that it read in Step 2. This ensures that the connector does not miss any updates. If the connector stops again for any reason, upon restart, the connector continues streaming changes from where it previously left off.

Table 1. Options for the snapshot.mode connector configuration property
OptionDescription

always

The connector always performs a snapshot when it starts. After the snapshot completes, the connector continues streaming changes from step 3 in the above sequence. This mode is useful in these situations:

  • It is known that some WAL segments have been deleted and are no longer available.

  • After a cluster failure, a new primary has been promoted. The always snapshot mode ensures that the connector does not miss any changes that were made after the new primary had been promoted but before the connector was restarted on the new primary.

never

The connector never performs snapshots. When a connector is configured this way, its behavior when it starts is as follows. If there is a previously stored LSN in the Kafka offsets topic, the connector continues streaming changes from that position. If no LSN has been stored, the connector starts streaming changes from the point in time when the PostgreSQL logical replication slot was created on the server. The never snapshot mode is useful only when you know all data of interest is still reflected in the WAL.

initial (default)

The connector performs a database snapshot when no Kafka offsets topic exists. After the database snapshot completes the Kafka offsets topic is written. If there is a previously stored LSN in the Kafka offsets topic, the connector continues streaming changes from that position.

initial_only

The connector performs a database snapshot and stops before streaming any change event records. If the connector had started but did not complete a snapshot before stopping, the connector restarts the snapshot process and stops when the snapshot completes.

exported

Deprecated, all modes are lockless.

custom

The custom snapshot mode lets you inject your own implementation of the io.debezium.connector.postgresql.spi.Snapshotter interface. Set the snapshot.custom.class configuration property to the class on the classpath of your Kafka Connect cluster or included in the JAR if using the EmbeddedEngine. For more details, see custom snapshotter SPI.

Ad hoc snapshots

By default, a connector runs an initial snapshot operation only after it starts for the first time. Following this initial snapshot, under normal circumstances, the connector does not repeat the snapshot process. Any future change event data that the connector captures comes in through the streaming process only.

However, in some situations the data that the connector obtained during the initial snapshot might become stale, lost, or incomplete. To provide a mechanism for recapturing table data, Debezium includes an option to perform ad hoc snapshots. You might want to perform an ad hoc snapshot after any of the following changes occur in your Debezium environment:

  • The connector configuration is modified to capture a different set of tables.

  • Kafka topics are deleted and must be rebuilt.

  • Data corruption occurs due to a configuration error or some other problem.

You can re-run a snapshot for a table for which you previously captured a snapshot by initiating a so-called ad-hoc snapshot. Ad hoc snapshots require the use of signaling tables. You initiate an ad hoc snapshot by sending a signal request to the Debezium signaling table.

When you initiate an ad hoc snapshot of an existing table, the connector appends content to the topic that already exists for the table. If a previously existing topic was removed, Debezium can create a topic automatically if automatic topic creation is enabled.

Ad hoc snapshot signals specify the tables to include in the snapshot. The snapshot can capture the entire contents of the database, or capture only a subset of the tables in the database. Also, the snapshot can capture a subset of the contents of the table(s) in the database.

You specify the tables to capture by sending an execute-snapshot message to the signaling table. Set the type of the execute-snapshot signal to incremental or blocking, and provide the names of the tables to include in the snapshot, as described in the following table:

Table 2. Example of an ad hoc execute-snapshot signal record
FieldDefaultValue

type

incremental

Specifies the type of snapshot that you want to run.
Currently, you can request incremental or blocking snapshots.

data-collections

N/A

An array that contains regular expressions matching the fully-qualified names of the table to be snapshotted.
The format of the names is the same as for the signal.data.collection configuration option.

additional-condition

N/A

An optional string, which specifies a condition based on the column(s) of the table(s), to capture a subset of the contents of the table(s).

This property is deprecated. To specify criteria for defining the subset of data that you want the snapshot to capture, use the additional-conditions parameter.

additional-conditions

N/A

An optional array that specifies a set of additional conditions that the connector evaluates to determine the subset of records to include in a snapshot.
Each additional condition is an object that specifies the criteria for filtering the data that an ad hoc snapshot captures. You can set the following parameters for each additional condition:

    data-collection

    The fully-qualified name of the table that the filter applies to. You can apply different filters to each table.

    filter

    Specifies column values that must be present in a database record for the snapshot to include it, for example, “color=’blue’”.

    The values that you assign to the filter parameter are the same types of values that you might specify in the WHERE clause of SELECT statements when you set the snapshot.select.statement.overrides property for a blocking snapshot. In earlier Debezium releases, an explicit filter parameter was not defined for snapshot signals; instead, filter criteria were implied by the values that were specified for the now deprecated additional-condition parameter.

surrogate-key

N/A

An optional string that specifies the column name that the connector uses as the primary key of a table during the snapshot process.

Triggering an ad hoc incremental snapshot

You initiate an ad hoc incremental snapshot by adding an entry with the execute-snapshot signal type to the signaling table. After the connector processes the message, it begins the snapshot operation. The snapshot process reads the first and last primary key values and uses those values as the start and end point for each table. Based on the number of entries in the table, and the configured chunk size, Debezium divides the table into chunks, and proceeds to snapshot each chunk, in succession, one at a time.

For more information, see Incremental snapshots.

Triggering an ad hoc blocking snapshot

You initiate an ad hoc blocking snapshot by adding an entry with the execute-snapshot signal type to the signaling table. After the connector processes the message, it begins the snapshot operation. The connector temporarily stops streaming, and then initiates a snapshot of the specified table, following the same process that it uses during an initial snapshot. After the snapshot completes, the connector resumes streaming.

For more information, see Blocking snapshots.

Incremental snapshots

To provide flexibility in managing snapshots, Debezium includes a supplementary snapshot mechanism, known as incremental snapshotting. Incremental snapshots rely on the Debezium mechanism for sending signals to a Debezium connector. Incremental snapshots are based on the DDD-3 design document.

In an incremental snapshot, instead of capturing the full state of a database all at once, as in an initial snapshot, Debezium captures each table in phases, in a series of configurable chunks. You can specify the tables that you want the snapshot to capture and the size of each chunk. The chunk size determines the number of rows that the snapshot collects during each fetch operation on the database. The default chunk size for incremental snapshots is 1024 rows.

As an incremental snapshot proceeds, Debezium uses watermarks to track its progress, maintaining a record of each table row that it captures. This phased approach to capturing data provides the following advantages over the standard initial snapshot process:

  • You can run incremental snapshots in parallel with streamed data capture, instead of postponing streaming until the snapshot completes. The connector continues to capture near real-time events from the change log throughout the snapshot process, and neither operation blocks the other.

  • If the progress of an incremental snapshot is interrupted, you can resume it without losing any data. After the process resumes, the snapshot begins at the point where it stopped, rather than recapturing the table from the beginning.

  • You can run an incremental snapshot on demand at any time, and repeat the process as needed to adapt to database updates. For example, you might re-run a snapshot after you modify the connector configuration to add a table to its table.include.list property.

Incremental snapshot process

When you run an incremental snapshot, Debezium sorts each table by primary key and then splits the table into chunks based on the configured chunk size. Working chunk by chunk, it then captures each table row in a chunk. For each row that it captures, the snapshot emits a READ event. That event represents the value of the row when the snapshot for the chunk began.

As a snapshot proceeds, it’s likely that other processes continue to access the database, potentially modifying table records. To reflect such changes, INSERT, UPDATE, or DELETE operations are committed to the transaction log as per usual. Similarly, the ongoing Debezium streaming process continues to detect these change events and emits corresponding change event records to Kafka.

How Debezium resolves collisions among records with the same primary key

In some cases, the UPDATE or DELETE events that the streaming process emits are received out of sequence. That is, the streaming process might emit an event that modifies a table row before the snapshot captures the chunk that contains the READ event for that row. When the snapshot eventually emits the corresponding READ event for the row, its value is already superseded. To ensure that incremental snapshot events that arrive out of sequence are processed in the correct logical order, Debezium employs a buffering scheme for resolving collisions. Only after collisions between the snapshot events and the streamed events are resolved does Debezium emit an event record to Kafka.

Snapshot window

To assist in resolving collisions between late-arriving READ events and streamed events that modify the same table row, Debezium employs a so-called snapshot window. The snapshot windows demarcates the interval during which an incremental snapshot captures data for a specified table chunk. Before the snapshot window for a chunk opens, Debezium follows its usual behavior and emits events from the transaction log directly downstream to the target Kafka topic. But from the moment that the snapshot for a particular chunk opens, until it closes, Debezium performs a de-duplication step to resolve collisions between events that have the same primary key..

For each data collection, the Debezium emits two types of events, and stores the records for them both in a single destination Kafka topic. The snapshot records that it captures directly from a table are emitted as READ operations. Meanwhile, as users continue to update records in the data collection, and the transaction log is updated to reflect each commit, Debezium emits UPDATE or DELETE operations for each change.

As the snapshot window opens, and Debezium begins processing a snapshot chunk, it delivers snapshot records to a memory buffer. During the snapshot windows, the primary keys of the READ events in the buffer are compared to the primary keys of the incoming streamed events. If no match is found, the streamed event record is sent directly to Kafka. If Debezium detects a match, it discards the buffered READ event, and writes the streamed record to the destination topic, because the streamed event logically supersede the static snapshot event. After the snapshot window for the chunk closes, the buffer contains only READ events for which no related transaction log events exist. Debezium emits these remaining READ events to the table’s Kafka topic.

The connector repeats the process for each snapshot chunk.

The Debezium connector for PostgreSQL does not support schema changes while an incremental snapshot is running. If a schema change is performed before the incremental snapshot start but after sending the signal then passthrough config option database.autosave is set to conservative to correctly process the schema change.

Triggering an incremental snapshot

Currently, the only way to initiate an incremental snapshot is to send an ad hoc snapshot signal to the signaling table on the source database.

You submit a signal to the signaling table as SQL INSERT queries.

After Debezium detects the change in the signaling table, it reads the signal, and runs the requested snapshot operation.

The query that you submit specifies the tables to include in the snapshot, and, optionally, specifies the kind of snapshot operation. Currently, the only valid option for snapshots operations is the default value, incremental.

To specify the tables to include in the snapshot, provide a data-collections array that lists the tables or an array of regular expressions used to match tables, for example,

{"data-collections": ["public.MyFirstTable", "public.MySecondTable"]}

The data-collections array for an incremental snapshot signal has no default value. If the data-collections array is empty, Debezium detects that no action is required and does not perform a snapshot.

If the name of a table that you want to include in a snapshot contains a dot (.) in the name of the database, schema, or table, to add the table to the data-collections array, you must escape each part of the name in double quotes.

For example, to include a table that exists in the public schema and that has the name My.Table, use the following format: “public”.”My.Table”.

Prerequisites

Using a source signaling channel to trigger an incremental snapshot

  1. Send a SQL query to add the ad hoc incremental snapshot request to the signaling table:

    1. INSERT INTO <signalTable> (id, type, data) VALUES ('<id>', '<snapshotType>', '{"data-collections": ["<tableName>","<tableName>"],"type":"<snapshotType>","additional-conditions":[{"data-collection": "<tableName>", "filter": "<additional-condition>"}]}');

    For example,

    1. INSERT INTO myschema.debezium_signal (id, type, data) (1)
    2. values ('ad-hoc-1', (2)
    3. 'execute-snapshot', (3)
    4. '{"data-collections": ["schema1.table1", "schema2.table2"], (4)
    5. "type":"incremental"}, (5)
    6. "additional-conditions":[{"data-collection": "schema1.table1" ,"filter":"color='blue'"}]}'); (6)

    The values of the id,type, and data parameters in the command correspond to the fields of the signaling table.

    The following table describes the parameters in the example:

    Table 3. Descriptions of fields in a SQL command for sending an incremental snapshot signal to the signaling table
    ItemValueDescription

    1

    myschema.debezium_signal

    Specifies the fully-qualified name of the signaling table on the source database.

    2

    ad-hoc-1

    The id parameter specifies an arbitrary string that is assigned as the id identifier for the signal request.
    Use this string to identify logging messages to entries in the signaling table. Debezium does not use this string. Rather, during the snapshot, Debezium generates its own id string as a watermarking signal.

    3

    execute-snapshot

    The type parameter specifies the operation that the signal is intended to trigger.

    4

    data-collections

    A required component of the data field of a signal that specifies an array of table names or regular expressions to match table names to include in the snapshot.
    The array lists regular expressions which match tables by their fully-qualified names, using the same format as you use to specify the name of the connector’s signaling table in the signal.data.collection configuration property.

    5

    incremental

    An optional type component of the data field of a signal that specifies the kind of snapshot operation to run.
    Currently, the only valid option is the default value, incremental.
    If you do not specify a value, the connector runs an incremental snapshot.

    6

    additional-conditions

    An optional array that specifies a set of additional conditions that the connector evaluates to determine the subset of records to include in a snapshot.
    Each additional condition is an object with data-collection and filter properties. You can specify different filters for each data collection.
    * The data-collection property is the fully-qualified name of the data collection for which the filter will be applied. For more information about the additional-conditions parameter, see Ad hoc incremental snapshots with additional-conditions.

Ad hoc incremental snapshots with additional-conditions

If you want a snapshot to include only a subset of the content in a table, you can modify the signal request by appending an additional-conditions parameter to the snapshot signal.

The SQL query for a typical snapshot takes the following form:

  1. SELECT * FROM <tableName> ....

By adding an additional-conditions parameter, you append a WHERE condition to the SQL query, as in the following example:

  1. SELECT * FROM <data-collection> WHERE <filter> ....

The following example shows a SQL query to send an ad hoc incremental snapshot request with an additional condition to the signaling table:

  1. INSERT INTO <signalTable> (id, type, data) VALUES ('<id>', '<snapshotType>', '{"data-collections": ["<tableName>","<tableName>"],"type":"<snapshotType>","additional-conditions":[{"data-collection": "<tableName>", "filter": "<additional-condition>"}]}');

For example, suppose you have a products table that contains the following columns:

  • id (primary key)

  • color

  • quantity

If you want an incremental snapshot of the products table to include only the data items where color=blue, you can use the following SQL statement to trigger the snapshot:

  1. INSERT INTO myschema.debezium_signal (id, type, data) VALUES('ad-hoc-1', 'execute-snapshot', '{"data-collections": ["schema1.products"],"type":"incremental", "additional-conditions":[{"data-collection": "schema1.products", "filter": "color=blue"}]}');

The additional-conditions parameter also enables you to pass conditions that are based on more than one column. For example, using the products table from the previous example, you can submit a query that triggers an incremental snapshot that includes the data of only those items for which color=blue and quantity>10:

  1. INSERT INTO myschema.debezium_signal (id, type, data) VALUES('ad-hoc-1', 'execute-snapshot', '{"data-collections": ["schema1.products"],"type":"incremental", "additional-conditions":[{"data-collection": "schema1.products", "filter": "color=blue AND quantity>10"}]}');

The following example, shows the JSON for an incremental snapshot event that is captured by a connector.

Example: Incremental snapshot event message

  1. {
  2. "before":null,
  3. "after": {
  4. "pk":"1",
  5. "value":"New data"
  6. },
  7. "source": {
  8. ...
  9. "snapshot":"incremental" (1)
  10. },
  11. "op":"r", (2)
  12. "ts_ms":"1620393591654",
  13. "transaction":null
  14. }
ItemField nameDescription

1

snapshot

Specifies the type of snapshot operation to run.
Currently, the only valid option is the default value, incremental.
Specifying a type value in the SQL query that you submit to the signaling table is optional.
If you do not specify a value, the connector runs an incremental snapshot.

2

op

Specifies the event type.
The value for snapshot events is r, signifying a READ operation.

Using the Kafka signaling channel to trigger an incremental snapshot

You can send a message to the configured Kafka topic to request the connector to run an ad hoc incremental snapshot.

The key of the Kafka message must match the value of the topic.prefix connector configuration option.

The value of the message is a JSON object with type and data fields.

The signal type is execute-snapshot, and the data field must have the following fields:

Table 4. Execute snapshot data fields
FieldDefaultValue

type

incremental

The type of the snapshot to be executed. Currently Debezium supports only the incremental type.
See the next section for more details.

data-collections

N/A

An array of comma-separated regular expressions that match the fully-qualified names of tables to include in the snapshot.
Specify the names by using the same format as is required for the signal.data.collection configuration option.

additional-condition

N/A

An optional string that specifies a condition that the connector evaluates to designate a subset of records to include in a snapshot.

This property is deprecated and should be replaced by the additional-conditions property.

additional-conditions

N/A

An optional array of additional conditions that specifies criteria that the connector evaluates to designate a subset of records to include in a snapshot.
Each additional condition is an object that specifies the criteria for filtering the data that an ad hoc snapshot captures. You can set the following parameters for each additional condition: data-collection:: The fully-qualified name of the table that the filter applies to. You can apply different filters to each table. filter:: Specifies column values that must be present in a database record for the snapshot to include it, for example, “color=’blue’”.

The values that you assign to the filter parameter are the same types of values that you might specify in the WHERE clause of SELECT statements when you set the snapshot.select.statement.overrides property for a blocking snapshot. In earlier Debezium releases, an explicit filter parameter was not defined for snapshot signals; instead, filter criteria were implied by the values that were specified for the now deprecated additional-condition parameter.

An example of the execute-snapshot Kafka message:

  1. Key = `test_connector`
  2. Value = `{"type":"execute-snapshot","data": {"data-collections": ["schema1.table1", "schema1.table2"], "type": "INCREMENTAL"}}`

Ad hoc incremental snapshots with additional-condition

Debezium uses the additional-conditions field to select a subset of a table’s content.

Typically, when Debezium runs a snapshot, it runs a SQL query such as:

SELECT * FROM _<tableName>_ …​.

When the snapshot request includes an additional-conditions property, the data-collection and filter parameters of the property are appended to the SQL query, for example:

SELECT * FROM _<data-collection>_ WHERE _<filter>_ …​.

For example, given a products table with the columns id (primary key), color, and brand, if you want a snapshot to include only content for which color='blue', when you request the snapshot, you could add the additional-conditions property to filter the content:

  1. Key = `test_connector`
  2. Value = `{"type":"execute-snapshot","data": {"data-collections": ["schema1.products"], "type": "INCREMENTAL", "additional-conditions": [{"data-collection": "schema1.products" ,"filter":"color='blue'"}]}}`

You can use the additional-conditions property to pass conditions based on multiple columns. For example, using the same products table as in the previous example, if you want a snapshot to include only the content from the products table for which color='blue', and brand='MyBrand', you could send the following request:

  1. Key = `test_connector`
  2. Value = `{"type":"execute-snapshot","data": {"data-collections": ["schema1.products"], "type": "INCREMENTAL", "additional-conditions": [{"data-collection": "schema1.products" ,"filter":"color='blue' AND brand='MyBrand'"}]}}`

Stopping an incremental snapshot

You can also stop an incremental snapshot by sending a signal to the table on the source database. You submit a stop snapshot signal to the table by sending a SQL INSERT query.

After Debezium detects the change in the signaling table, it reads the signal, and stops the incremental snapshot operation if it’s in progress.

The query that you submit specifies the snapshot operation of incremental, and, optionally, the tables of the current running snapshot to be removed.

Prerequisites

Using a source signaling channel to stop an incremental snapshot

  1. Send a SQL query to stop the ad hoc incremental snapshot to the signaling table:

    1. INSERT INTO <signalTable> (id, type, data) values ('<id>', 'stop-snapshot', '{"data-collections": ["<tableName>","<tableName>"],"type":"incremental"}');

    For example,

    1. INSERT INTO myschema.debezium_signal (id, type, data) (1)
    2. values ('ad-hoc-1', (2)
    3. 'stop-snapshot', (3)
    4. '{"data-collections": ["schema1.table1", "schema2.table2"], (4)
    5. "type":"incremental"}'); (5)

    The values of the id, type, and data parameters in the signal command correspond to the fields of the signaling table.

    The following table describes the parameters in the example:

    Table 5. Descriptions of fields in a SQL command for sending a stop incremental snapshot signal to the signaling table
    ItemValueDescription

    1

    myschema.debezium_signal

    Specifies the fully-qualified name of the signaling table on the source database.

    2

    ad-hoc-1

    The id parameter specifies an arbitrary string that is assigned as the id identifier for the signal request.
    Use this string to identify logging messages to entries in the signaling table. Debezium does not use this string.

    3

    stop-snapshot

    Specifies type parameter specifies the operation that the signal is intended to trigger.

    4

    data-collections

    An optional component of the data field of a signal that specifies an array of table names or regular expressions to match table names to remove from the snapshot.
    The array lists regular expressions which match tables by their fully-qualified names, using the same format as you use to specify the name of the connector’s signaling table in the signal.data.collection configuration property. If this component of the data field is omitted, the signal stops the entire incremental snapshot that is in progress.

    5

    incremental

    A required component of the data field of a signal that specifies the kind of snapshot operation that is to be stopped.
    Currently, the only valid option is incremental.
    If you do not specify a type value, the signal fails to stop the incremental snapshot.

Using the Kafka signaling channel to stop an incremental snapshot

You can send a signal message to the configured Kafka signaling topic to stop an ad hoc incremental snapshot.

The key of the Kafka message must match the value of the topic.prefix connector configuration option.

The value of the message is a JSON object with type and data fields.

The signal type is stop-snapshot, and the data field must have the following fields:

Table 6. Execute snapshot data fields
FieldDefaultValue

type

incremental

The type of the snapshot to be executed. Currently Debezium supports only the incremental type.
See the next section for more details.

data-collections

N/A

An optional array of comma-separated regular expressions that match the fully-qualified names of the tables to include in the snapshot.
Specify the names by using the same format as is required for the signal.data.collection configuration option.

The following example shows a typical stop-snapshot Kafka message:

  1. Key = `test_connector`
  2. Value = `{"type":"stop-snapshot","data": {"data-collections": ["schema1.table1", "schema1.table2"], "type": "INCREMENTAL"}}`

Custom snapshotter SPI

For more advanced uses, you can provide an implementation of the io.debezium.connector.postgresql.spi.Snapshotter interface. This interface allows control of most of the aspects of how the connector performs snapshots. This includes whether or not to take a snapshot, the options for opening the snapshot transaction, and whether to take locks.

Following is the full API for the interface. All built-in snapshot modes implement this interface.

  1. /**
  2. * This interface is used to determine details about the snapshot process:
  3. *
  4. * Namely:
  5. * - Should a snapshot occur at all
  6. * - Should streaming occur
  7. * - What queries should be used to snapshot
  8. *
  9. * While many default snapshot modes are provided with Debezium,
  10. * a custom implementation of this interface can be provided by the implementor, which
  11. * can provide more advanced functionality, such as partial snapshots.
  12. *
  13. * Implementations must return true for either {@link #shouldSnapshot()} or {@link #shouldStream()}
  14. * or true for both.
  15. */
  16. @Incubating
  17. public interface Snapshotter {
  18. void init(PostgresConnectorConfig config, OffsetState sourceInfo,
  19. SlotState slotState);
  20. /**
  21. * @return true if the snapshotter should take a snapshot
  22. */
  23. boolean shouldSnapshot();
  24. /**
  25. * @return true if the snapshotter should stream after taking a snapshot
  26. */
  27. boolean shouldStream();
  28. /**
  29. *
  30. * @return true if streaming should resume from the start of the snapshot
  31. * transaction, or false for when a connector resumes and takes a snapshot,
  32. * streaming should resume from where streaming previously left off.
  33. */
  34. default boolean shouldStreamEventsStartingFromSnapshot() {
  35. return true;
  36. }
  37. /**
  38. * Generate a valid postgres query string for the specified table, or an empty {@link Optional}
  39. * to skip snapshotting this table (but that table will still be streamed from)
  40. *
  41. * @param tableId the table to generate a query for
  42. * @param snapshotSelectColumns the columns to be used in the snapshot select based on the column
  43. * include/exclude filters
  44. * @return a valid query string, or none to skip snapshotting this table
  45. */
  46. Optional<String> buildSnapshotQuery(TableId tableId, List<String> snapshotSelectColumns);
  47. /**
  48. * Return a new string that set up the transaction for snapshotting
  49. *
  50. * @param newSlotInfo if a new slow was created for snapshotting, this contains information from
  51. * the `create_replication_slot` command
  52. */
  53. default String snapshotTransactionIsolationLevelStatement(SlotCreationResult newSlotInfo) {
  54. // we're using the same isolation level that pg_backup uses
  55. return "SET TRANSACTION ISOLATION LEVEL SERIALIZABLE, READ ONLY, DEFERRABLE;";
  56. }
  57. /**
  58. * Returns a SQL statement for locking the given tables during snapshotting, if required by the specific snapshotter
  59. * implementation.
  60. */
  61. default Optional<String> snapshotTableLockingStatement(Duration lockTimeout, Set<TableId> tableIds) {
  62. String lineSeparator = System.lineSeparator();
  63. StringBuilder statements = new StringBuilder();
  64. statements.append("SET lock_timeout = ").append(lockTimeout.toMillis()).append(";").append(lineSeparator);
  65. // we're locking in ACCESS SHARE MODE to avoid concurrent schema changes while we're taking the snapshot
  66. // this does not prevent writes to the table, but prevents changes to the table's schema....
  67. // DBZ-298 Quoting name in case it has been quoted originally; it doesn't do harm if it hasn't been quoted
  68. tableIds.forEach(tableId -> statements.append("LOCK TABLE ")
  69. .append(tableId.toDoubleQuotedString())
  70. .append(" IN ACCESS SHARE MODE;")
  71. .append(lineSeparator));
  72. return Optional.of(statements.toString());
  73. }
  74. /**
  75. * Lifecycle hook called once the snapshot phase is finished.
  76. */
  77. default void snapshotCompleted() {
  78. // no operation
  79. }
  80. }

Blocking snapshots

To provide more flexibility in managing snapshots, Debezium includes a supplementary ad hoc snapshot mechanism, known as a blocking snapshot. Blocking snapshots rely on the Debezium mechanism for sending signals to a Debezium connector.

A blocking snapshot behaves just like an initial snapshot, except that you can trigger it at run time.

You might want to run a blocking snapshot rather than use the standard initial snapshot process in the following situations:

  • You add a new table and you want to complete the snapshot while the connector is running.

  • You add a large table, and you want the snapshot to complete in less time than is possible with an incremental snapshot.

Blocking snapshot process

When you run a blocking snapshot, Debezium stops streaming, and then initiates a snapshot of the specified table, following the same process that it uses during an initial snapshot. After the snapshot completes, the streaming is resumed.

Configure snapshot

You can set the following properties in the data component of a signal:

  • data-collections: to specify which tables must be snapshot

  • additional-conditions: You can specify different filters for different table.

    • The data-collection property is the fully-qualified name of the table for which the filter will be applied.

    • The filter property will have the same value used in the snapshot.select.statement.overrides

For example:

  1. {"type": "blocking", "data-collections": ["schema1.table1", "schema1.table2"], "additional-conditions": [{"data-collection": "schema1.table1", "filter": "SELECT * FROM [schema1].[table1] WHERE column1 = 0 ORDER BY column2 DESC"}, {"data-collection": "schema1.table2", "filter": "SELECT * FROM [schema1].[table2] WHERE column2 > 0"}]}

Possible duplicates

A delay might exist between the time that you send the signal to trigger the snapshot, and the time when streaming stops and the snapshot starts. As a result of this delay, after the snapshot completes, the connector might emit some event records that duplicate records captured by the snapshot.

Streaming changes

The PostgreSQL connector typically spends the vast majority of its time streaming changes from the PostgreSQL server to which it is connected. This mechanism relies on PostgreSQL’s replication protocol. This protocol enables clients to receive changes from the server as they are committed in the server’s transaction log at certain positions, which are referred to as Log Sequence Numbers (LSNs).

Whenever the server commits a transaction, a separate server process invokes a callback function from the logical decoding plug-in. This function processes the changes from the transaction, converts them to a specific format (Protobuf or JSON in the case of Debezium plug-in) and writes them on an output stream, which can then be consumed by clients.

The Debezium PostgreSQL connector acts as a PostgreSQL client. When the connector receives changes it transforms the events into Debezium create, update, or delete events that include the LSN of the event. The PostgreSQL connector forwards these change events in records to the Kafka Connect framework, which is running in the same process. The Kafka Connect process asynchronously writes the change event records in the same order in which they were generated to the appropriate Kafka topic.

Periodically, Kafka Connect records the most recent offset in another Kafka topic. The offset indicates source-specific position information that Debezium includes with each event. For the PostgreSQL connector, the LSN recorded in each change event is the offset.

When Kafka Connect gracefully shuts down, it stops the connectors, flushes all event records to Kafka, and records the last offset received from each connector. When Kafka Connect restarts, it reads the last recorded offset for each connector, and starts each connector at its last recorded offset. When the connector restarts, it sends a request to the PostgreSQL server to send the events starting just after that position.

The PostgreSQL connector retrieves schema information as part of the events sent by the logical decoding plug-in. However, the connector does not retrieve information about which columns compose the primary key. The connector obtains this information from the JDBC metadata (side channel). If the primary key definition of a table changes (by adding, removing or renaming primary key columns), there is a tiny period of time when the primary key information from JDBC is not synchronized with the change event that the logical decoding plug-in generates. During this tiny period, a message could be created with an inconsistent key structure. To prevent this inconsistency, update primary key structures as follows:

  1. Put the database or an application into a read-only mode.

  2. Let Debezium process all remaining events.

  3. Stop Debezium.

  4. Update the primary key definition in the relevant table.

  5. Put the database or the application into read/write mode.

  6. Restart Debezium.

PostgreSQL 10+ logical decoding support (pgoutput)

As of PostgreSQL 10+, there is a logical replication stream mode, called pgoutput that is natively supported by PostgreSQL. This means that a Debezium PostgreSQL connector can consume that replication stream without the need for additional plug-ins. This is particularly valuable for environments where installation of plug-ins is not supported or not allowed.

For more information, see Setting up PostgreSQL.

Topic names

By default, the PostgreSQL connector writes change events for all INSERT, UPDATE, and DELETE operations that occur in a table to a single Apache Kafka topic that is specific to that table. The connector uses the following convention to name change event topics:

topicPrefix.schemaName.tableName

The following list provides definitions for the components of the default name:

topicPrefix

The topic prefix as specified by the topic.prefix configuration property.

schemaName

The name of the database schema in which the change event occurred.

tableName

The name of the database table in which the change event occurred.

For example, suppose that fulfillment is the logical server name in the configuration for a connector that is capturing changes in a PostgreSQL installation that has a postgres database and an inventory schema that contains four tables: products, products_on_hand, customers, and orders. The connector would stream records to these four Kafka topics:

  • fulfillment.inventory.products

  • fulfillment.inventory.products_on_hand

  • fulfillment.inventory.customers

  • fulfillment.inventory.orders

Now suppose that the tables are not part of a specific schema but were created in the default public PostgreSQL schema. The names of the Kafka topics would be:

  • fulfillment.public.products

  • fulfillment.public.products_on_hand

  • fulfillment.public.customers

  • fulfillment.public.orders

The connector applies similar naming conventions to label its transaction metadata topics.

If the default topic name do not meet your requirements, you can configure custom topic names. To configure custom topic names, you specify regular expressions in the logical topic routing SMT. For more information about using the logical topic routing SMT to customize topic naming, see Topic routing.

Transaction metadata

Debezium can generate events that represent transaction boundaries and that enrich data change event messages.

Limits on when Debezium receives transaction metadata

Debezium registers and receives metadata only for transactions that occur after you deploy the connector. Metadata for transactions that occur before you deploy the connector is not available.

For every transaction BEGIN and END, Debezium generates an event that contains the following fields:

status

BEGIN or END.

id

String representation of the unique transaction identifier composed of Postgres transaction ID itself and LSN of given operation separated by colon, i.e. the format is txID:LSN.

ts_ms

The time of a transaction boundary event (BEGIN or END event) at the data source. If the data source does not provide Debezium with the event time, then the field instead represents the time at which Debezium processes the event.

event_count (for END events)

Total number of events emmitted by the transaction.

data_collections (for END events)

An array of pairs of data_collection and event_count elements that indicates the number of events that the connector emits for changes that originate from a data collection.

Example

  1. {
  2. "status": "BEGIN",
  3. "id": "571:53195829",
  4. "ts_ms": 1486500577125,
  5. "event_count": null,
  6. "data_collections": null
  7. }
  8. {
  9. "status": "END",
  10. "id": "571:53195832",
  11. "ts_ms": 1486500577691,
  12. "event_count": 2,
  13. "data_collections": [
  14. {
  15. "data_collection": "s1.a",
  16. "event_count": 1
  17. },
  18. {
  19. "data_collection": "s2.a",
  20. "event_count": 1
  21. }
  22. ]
  23. }

Unless overridden via the topic.transaction option, transaction events are written to the topic named .transaction.

Change data event enrichment

When transaction metadata is enabled the data message Envelope is enriched with a new transaction field. This field provides information about every event in the form of a composite of fields:

id

String representation of unique transaction identifier.

total_order

The absolute position of the event among all events generated by the transaction.

data_collection_order

The per-data collection position of the event among all events that were emitted by the transaction.

Following is an example of a message:

  1. {
  2. "before": null,
  3. "after": {
  4. "pk": "2",
  5. "aa": "1"
  6. },
  7. "source": {
  8. ...
  9. },
  10. "op": "c",
  11. "ts_ms": "1580390884335",
  12. "transaction": {
  13. "id": "571:53195832",
  14. "total_order": "1",
  15. "data_collection_order": "1"
  16. }
  17. }

Data change events

The Debezium PostgreSQL connector generates a data change event for each row-level INSERT, UPDATE, and DELETE operation. Each event contains a key and a value. The structure of the key and the value depends on the table that was changed.

Debezium and Kafka Connect are designed around continuous streams of event messages. However, the structure of these events may change over time, which can be difficult for consumers to handle. To address this, each event contains the schema for its content or, if you are using a schema registry, a schema ID that a consumer can use to obtain the schema from the registry. This makes each event self-contained.

The following skeleton JSON shows the basic four parts of a change event. However, how you configure the Kafka Connect converter that you choose to use in your application determines the representation of these four parts in change events. A schema field is in a change event only when you configure the converter to produce it. Likewise, the event key and event payload are in a change event only if you configure a converter to produce it. If you use the JSON converter and you configure it to produce all four basic change event parts, change events have this structure:

  1. {
  2. "schema": { (1)
  3. ...
  4. },
  5. "payload": { (2)
  6. ...
  7. },
  8. "schema": { (3)
  9. ...
  10. },
  11. "payload": { (4)
  12. ...
  13. },
  14. }
Table 7. Overview of change event basic content
ItemField nameDescription

1

schema

The first schema field is part of the event key. It specifies a Kafka Connect schema that describes what is in the event key’s payload portion. In other words, the first schema field describes the structure of the primary key, or the unique key if the table does not have a primary key, for the table that was changed.

It is possible to override the table’s primary key by setting the message.key.columns connector configuration property. In this case, the first schema field describes the structure of the key identified by that property.

2

payload

The first payload field is part of the event key. It has the structure described by the previous schema field and it contains the key for the row that was changed.

3

schema

The second schema field is part of the event value. It specifies the Kafka Connect schema that describes what is in the event value’s payload portion. In other words, the second schema describes the structure of the row that was changed. Typically, this schema contains nested schemas.

4

payload

The second payload field is part of the event value. It has the structure described by the previous schema field and it contains the actual data for the row that was changed.

By default behavior is that the connector streams change event records to topics with names that are the same as the event’s originating table.

Starting with Kafka 0.10, Kafka can optionally record the event key and value with the timestamp at which the message was created (recorded by the producer) or written to the log by Kafka.

The PostgreSQL connector ensures that all Kafka Connect schema names adhere to the Avro schema name format. This means that the logical server name must start with a Latin letter or an underscore, that is, a-z, A-Z, or . Each remaining character in the logical server name and each character in the schema and table names must be a Latin letter, a digit, or an underscore, that is, a-z, A-Z, 0-9, or \. If there is an invalid character it is replaced with an underscore character.

This can lead to unexpected conflicts if the logical server name, a schema name, or a table name contains invalid characters, and the only characters that distinguish names from one another are invalid and thus replaced with underscores.

Change event keys

For a given table, the change event’s key has a structure that contains a field for each column in the primary key of the table at the time the event was created. Alternatively, if the table has REPLICA IDENTITY set to FULL or USING INDEX there is a field for each unique key constraint.

Consider a customers table defined in the public database schema and the example of a change event key for that table.

Example table

  1. CREATE TABLE customers (
  2. id SERIAL,
  3. first_name VARCHAR(255) NOT NULL,
  4. last_name VARCHAR(255) NOT NULL,
  5. email VARCHAR(255) NOT NULL,
  6. PRIMARY KEY(id)
  7. );

Example change event key

If the topic.prefix connector configuration property has the value PostgreSQL_server, every change event for the customers table while it has this definition has the same key structure, which in JSON looks like this:

  1. {
  2. "schema": { (1)
  3. "type": "struct",
  4. "name": "PostgreSQL_server.public.customers.Key", (2)
  5. "optional": false, (3)
  6. "fields": [ (4)
  7. {
  8. "name": "id",
  9. "index": "0",
  10. "schema": {
  11. "type": "INT32",
  12. "optional": "false"
  13. }
  14. }
  15. ]
  16. },
  17. "payload": { (5)
  18. "id": "1"
  19. },
  20. }
Table 8. Description of change event key
ItemField nameDescription

1

schema

The schema portion of the key specifies a Kafka Connect schema that describes what is in the key’s payload portion.

2

PostgreSQL_server.inventory.customers.Key

Name of the schema that defines the structure of the key’s payload. This schema describes the structure of the primary key for the table that was changed. Key schema names have the format connector-name.database-name.table-name.Key. In this example:

  • PostgreSQL_server is the name of the connector that generated this event.

  • inventory is the database that contains the table that was changed.

  • customers is the table that was updated.

3

optional

Indicates whether the event key must contain a value in its payload field. In this example, a value in the key’s payload is required. A value in the key’s payload field is optional when a table does not have a primary key.

4

fields

Specifies each field that is expected in the payload, including each field’s name, index, and schema.

5

payload

Contains the key for the row for which this change event was generated. In this example, the key, contains a single id field whose value is 1.

Although the column.exclude.list and column.include.list connector configuration properties allow you to capture only a subset of table columns, all columns in a primary or unique key are always included in the event’s key.

If the table does not have a primary or unique key, then the change event’s key is null. The rows in a table without a primary or unique key constraint cannot be uniquely identified.

Change event values

The value in a change event is a bit more complicated than the key. Like the key, the value has a schema section and a payload section. The schema section contains the schema that describes the Envelope structure of the payload section, including its nested fields. Change events for operations that create, update or delete data all have a value payload with an envelope structure.

Consider the same sample table that was used to show an example of a change event key:

  1. CREATE TABLE customers (
  2. id SERIAL,
  3. first_name VARCHAR(255) NOT NULL,
  4. last_name VARCHAR(255) NOT NULL,
  5. email VARCHAR(255) NOT NULL,
  6. PRIMARY KEY(id)
  7. );

The value portion of a change event for a change to this table varies according to the REPLICA IDENTITY setting and the operation that the event is for.

Replica identity

REPLICA IDENTITY is a PostgreSQL-specific table-level setting that determines the amount of information that is available to the logical decoding plug-in for UPDATE and DELETE events. More specifically, the setting of REPLICA IDENTITY controls what (if any) information is available for the previous values of the table columns involved, whenever an UPDATE or DELETE event occurs.

There are 4 possible values for REPLICA IDENTITY:

  • DEFAULT - The default behavior is that UPDATE and DELETE events contain the previous values for the primary key columns of a table if that table has a primary key. For an UPDATE event, only the primary key columns with changed values are present.

    If a table does not have a primary key, the connector does not emit UPDATE or DELETE events for that table. For a table without a primary key, the connector emits only create events. Typically, a table without a primary key is used for appending messages to the end of the table, which means that UPDATE and DELETE events are not useful.

  • NOTHING - Emitted events for UPDATE and DELETE operations do not contain any information about the previous value of any table column.

  • FULL - Emitted events for UPDATE and DELETE operations contain the previous values of all columns in the table.

  • INDEX index-name - Emitted events for UPDATE and DELETE operations contain the previous values of the columns contained in the specified index. UPDATE events also contain the indexed columns with the updated values.

create events

The following example shows the value portion of a change event that the connector generates for an operation that creates data in the customers table:

  1. {
  2. "schema": { (1)
  3. "type": "struct",
  4. "fields": [
  5. {
  6. "type": "struct",
  7. "fields": [
  8. {
  9. "type": "int32",
  10. "optional": false,
  11. "field": "id"
  12. },
  13. {
  14. "type": "string",
  15. "optional": false,
  16. "field": "first_name"
  17. },
  18. {
  19. "type": "string",
  20. "optional": false,
  21. "field": "last_name"
  22. },
  23. {
  24. "type": "string",
  25. "optional": false,
  26. "field": "email"
  27. }
  28. ],
  29. "optional": true,
  30. "name": "PostgreSQL_server.inventory.customers.Value", (2)
  31. "field": "before"
  32. },
  33. {
  34. "type": "struct",
  35. "fields": [
  36. {
  37. "type": "int32",
  38. "optional": false,
  39. "field": "id"
  40. },
  41. {
  42. "type": "string",
  43. "optional": false,
  44. "field": "first_name"
  45. },
  46. {
  47. "type": "string",
  48. "optional": false,
  49. "field": "last_name"
  50. },
  51. {
  52. "type": "string",
  53. "optional": false,
  54. "field": "email"
  55. }
  56. ],
  57. "optional": true,
  58. "name": "PostgreSQL_server.inventory.customers.Value",
  59. "field": "after"
  60. },
  61. {
  62. "type": "struct",
  63. "fields": [
  64. {
  65. "type": "string",
  66. "optional": false,
  67. "field": "version"
  68. },
  69. {
  70. "type": "string",
  71. "optional": false,
  72. "field": "connector"
  73. },
  74. {
  75. "type": "string",
  76. "optional": false,
  77. "field": "name"
  78. },
  79. {
  80. "type": "int64",
  81. "optional": false,
  82. "field": "ts_ms"
  83. },
  84. {
  85. "type": "boolean",
  86. "optional": true,
  87. "default": false,
  88. "field": "snapshot"
  89. },
  90. {
  91. "type": "string",
  92. "optional": false,
  93. "field": "db"
  94. },
  95. {
  96. "type": "string",
  97. "optional": false,
  98. "field": "schema"
  99. },
  100. {
  101. "type": "string",
  102. "optional": false,
  103. "field": "table"
  104. },
  105. {
  106. "type": "int64",
  107. "optional": true,
  108. "field": "txId"
  109. },
  110. {
  111. "type": "int64",
  112. "optional": true,
  113. "field": "lsn"
  114. },
  115. {
  116. "type": "int64",
  117. "optional": true,
  118. "field": "xmin"
  119. }
  120. ],
  121. "optional": false,
  122. "name": "io.debezium.connector.postgresql.Source", (3)
  123. "field": "source"
  124. },
  125. {
  126. "type": "string",
  127. "optional": false,
  128. "field": "op"
  129. },
  130. {
  131. "type": "int64",
  132. "optional": true,
  133. "field": "ts_ms"
  134. }
  135. ],
  136. "optional": false,
  137. "name": "PostgreSQL_server.inventory.customers.Envelope" (4)
  138. },
  139. "payload": { (5)
  140. "before": null, (6)
  141. "after": { (7)
  142. "id": 1,
  143. "first_name": "Anne",
  144. "last_name": "Kretchmar",
  145. "email": "annek@noanswer.org"
  146. },
  147. "source": { (8)
  148. "version": "2.4.1.Final",
  149. "connector": "postgresql",
  150. "name": "PostgreSQL_server",
  151. "ts_ms": 1559033904863,
  152. "snapshot": true,
  153. "db": "postgres",
  154. "sequence": "[\"24023119\",\"24023128\"]",
  155. "schema": "public",
  156. "table": "customers",
  157. "txId": 555,
  158. "lsn": 24023128,
  159. "xmin": null
  160. },
  161. "op": "c", (9)
  162. "ts_ms": 1559033904863 (10)
  163. }
  164. }
Table 9. Descriptions of create event value fields
ItemField nameDescription

1

schema

The value’s schema, which describes the structure of the value’s payload. A change event’s value schema is the same in every change event that the connector generates for a particular table.

2

name

In the schema section, each name field specifies the schema for a field in the value’s payload.

PostgreSQL_server.inventory.customers.Value is the schema for the payload’s before and after fields. This schema is specific to the customers table.

Names of schemas for before and after fields are of the form logicalName.tableName.Value, which ensures that the schema name is unique in the database. This means that when using the Avro converter, the resulting Avro schema for each table in each logical source has its own evolution and history.

3

name

io.debezium.connector.postgresql.Source is the schema for the payload’s source field. This schema is specific to the PostgreSQL connector. The connector uses it for all events that it generates.

4

name

PostgreSQL_server.inventory.customers.Envelope is the schema for the overall structure of the payload, where PostgreSQL_server is the connector name, inventory is the database, and customers is the table.

5

payload

The value’s actual data. This is the information that the change event is providing.

It may appear that the JSON representations of the events are much larger than the rows they describe. This is because the JSON representation must include the schema and the payload portions of the message. However, by using the Avro converter, you can significantly decrease the size of the messages that the connector streams to Kafka topics.

6

before

An optional field that specifies the state of the row before the event occurred. When the op field is c for create, as it is in this example, the before field is null since this change event is for new content.

Whether or not this field is available is dependent on the REPLICA IDENTITY setting for each table.

7

after

An optional field that specifies the state of the row after the event occurred. In this example, the after field contains the values of the new row’s id, first_name, last_name, and email columns.

8

source

Mandatory field that describes the source metadata for the event. This field contains information that you can use to compare this event with other events, with regard to the origin of the events, the order in which the events occurred, and whether events were part of the same transaction. The source metadata includes:

  • Debezium version

  • Connector type and name

  • Database and table that contains the new row

  • Stringified JSON array of additional offset information. The first value is always the last committed LSN, the second value is always the current LSN. Either value may be null.

  • Schema name

  • If the event was part of a snapshot

  • ID of the transaction in which the operation was performed

  • Offset of the operation in the database log

  • Timestamp for when the change was made in the database

9

op

Mandatory string that describes the type of operation that caused the connector to generate the event. In this example, c indicates that the operation created a row. Valid values are:

  • c = create

  • u = update

  • d = delete

  • r = read (applies to only snapshots)

  • t = truncate

  • m = message

10

ts_ms

Optional field that displays the time at which the connector processed the event. The time is based on the system clock in the JVM running the Kafka Connect task.

In the source object, ts_ms indicates the time that the change was made in the database. By comparing the value for payload.source.ts_ms with the value for payload.ts_ms, you can determine the lag between the source database update and Debezium.

update events

The value of a change event for an update in the sample customers table has the same schema as a create event for that table. Likewise, the event value’s payload has the same structure. However, the event value payload contains different values in an update event. Here is an example of a change event value in an event that the connector generates for an update in the customers table:

  1. {
  2. "schema": { ... },
  3. "payload": {
  4. "before": { (1)
  5. "id": 1
  6. },
  7. "after": { (2)
  8. "id": 1,
  9. "first_name": "Anne Marie",
  10. "last_name": "Kretchmar",
  11. "email": "annek@noanswer.org"
  12. },
  13. "source": { (3)
  14. "version": "2.4.1.Final",
  15. "connector": "postgresql",
  16. "name": "PostgreSQL_server",
  17. "ts_ms": 1559033904863,
  18. "snapshot": false,
  19. "db": "postgres",
  20. "schema": "public",
  21. "table": "customers",
  22. "txId": 556,
  23. "lsn": 24023128,
  24. "xmin": null
  25. },
  26. "op": "u", (4)
  27. "ts_ms": 1465584025523 (5)
  28. }
  29. }
Table 10. Descriptions of update event value fields
ItemField nameDescription

1

before

An optional field that contains values that were in the row before the database commit. In this example, only the primary key column, id, is present because the table’s REPLICA IDENTITY setting is, by default, DEFAULT. + For an update event to contain the previous values of all columns in the row, you would have to change the customers table by running ALTER TABLE customers REPLICA IDENTITY FULL.

2

after

An optional field that specifies the state of the row after the event occurred. In this example, the first_name value is now Anne Marie.

3

source

Mandatory field that describes the source metadata for the event. The source field structure has the same fields as in a create event, but some values are different. The source metadata includes:

  • Debezium version

  • Connector type and name

  • Database and table that contains the new row

  • Schema name

  • If the event was part of a snapshot (always false for update events)

  • ID of the transaction in which the operation was performed

  • Offset of the operation in the database log

  • Timestamp for when the change was made in the database

4

op

Mandatory string that describes the type of operation. In an update event value, the op field value is u, signifying that this row changed because of an update.

5

ts_ms

Optional field that displays the time at which the connector processed the event. The time is based on the system clock in the JVM running the Kafka Connect task.

In the source object, ts_ms indicates the time that the change was made in the database. By comparing the value for payload.source.ts_ms with the value for payload.ts_ms, you can determine the lag between the source database update and Debezium.

Updating the columns for a row’s primary/unique key changes the value of the row’s key. When a key changes, Debezium outputs three events: a DELETE event and a tombstone event with the old key for the row, followed by an event with the new key for the row. Details are in the next section.

Primary key updates

An UPDATE operation that changes a row’s primary key field(s) is known as a primary key change. For a primary key change, in place of sending an UPDATE event record, the connector sends a DELETE event record for the old key and a CREATE event record for the new (updated) key. These events have the usual structure and content, and in addition, each one has a message header related to the primary key change:

  • The DELETE event record has __debezium.newkey as a message header. The value of this header is the new primary key for the updated row.

  • The CREATE event record has __debezium.oldkey as a message header. The value of this header is the previous (old) primary key that the updated row had.

delete events

The value in a delete change event has the same schema portion as create and update events for the same table. The payload portion in a delete event for the sample customers table looks like this:

  1. {
  2. "schema": { ... },
  3. "payload": {
  4. "before": { (1)
  5. "id": 1
  6. },
  7. "after": null, (2)
  8. "source": { (3)
  9. "version": "2.4.1.Final",
  10. "connector": "postgresql",
  11. "name": "PostgreSQL_server",
  12. "ts_ms": 1559033904863,
  13. "snapshot": false,
  14. "db": "postgres",
  15. "schema": "public",
  16. "table": "customers",
  17. "txId": 556,
  18. "lsn": 46523128,
  19. "xmin": null
  20. },
  21. "op": "d", (4)
  22. "ts_ms": 1465581902461 (5)
  23. }
  24. }
Table 11. Descriptions of delete event value fields
ItemField nameDescription

1

before

Optional field that specifies the state of the row before the event occurred. In a delete event value, the before field contains the values that were in the row before it was deleted with the database commit.

In this example, the before field contains only the primary key column because the table’s REPLICA IDENTITY setting is DEFAULT.

2

after

Optional field that specifies the state of the row after the event occurred. In a delete event value, the after field is null, signifying that the row no longer exists.

3

source

Mandatory field that describes the source metadata for the event. In a delete event value, the source field structure is the same as for create and update events for the same table. Many source field values are also the same. In a delete event value, the ts_ms and lsn field values, as well as other values, might have changed. But the source field in a delete event value provides the same metadata:

  • Debezium version

  • Connector type and name

  • Database and table that contained the deleted row

  • Schema name

  • If the event was part of a snapshot (always false for delete events)

  • ID of the transaction in which the operation was performed

  • Offset of the operation in the database log

  • Timestamp for when the change was made in the database

4

op

Mandatory string that describes the type of operation. The op field value is d, signifying that this row was deleted.

5

ts_ms

Optional field that displays the time at which the connector processed the event. The time is based on the system clock in the JVM running the Kafka Connect task.

In the source object, ts_ms indicates the time that the change was made in the database. By comparing the value for payload.source.ts_ms with the value for payload.ts_ms, you can determine the lag between the source database update and Debezium.

A delete change event record provides a consumer with the information it needs to process the removal of this row.

For a consumer to be able to process a delete event generated for a table that does not have a primary key, set the table’s REPLICA IDENTITY to FULL. When a table does not have a primary key and the table’s REPLICA IDENTITY is set to DEFAULT or NOTHING, a delete event has no before field.

PostgreSQL connector events are designed to work with Kafka log compaction. Log compaction enables removal of some older messages as long as at least the most recent message for every key is kept. This lets Kafka reclaim storage space while ensuring that the topic contains a complete data set and can be used for reloading key-based state.

Tombstone events

When a row is deleted, the delete event value still works with log compaction, because Kafka can remove all earlier messages that have that same key. However, for Kafka to remove all messages that have that same key, the message value must be null. To make this possible, the PostgreSQL connector follows a delete event with a special tombstone event that has the same key but a null value.

truncate events

A truncate change event signals that a table has been truncated. The message key is null in this case, the message value looks like this:

  1. {
  2. "schema": { ... },
  3. "payload": {
  4. "source": { (1)
  5. "version": "2.4.1.Final",
  6. "connector": "postgresql",
  7. "name": "PostgreSQL_server",
  8. "ts_ms": 1559033904863,
  9. "snapshot": false,
  10. "db": "postgres",
  11. "schema": "public",
  12. "table": "customers",
  13. "txId": 556,
  14. "lsn": 46523128,
  15. "xmin": null
  16. },
  17. "op": "t", (2)
  18. "ts_ms": 1559033904961 (3)
  19. }
  20. }
Table 12. Descriptions of truncate event value fields
ItemField nameDescription

1

source

Mandatory field that describes the source metadata for the event. In a truncate event value, the source field structure is the same as for create, update, and delete events for the same table, provides this metadata:

  • Debezium version

  • Connector type and name

  • Database and table that contains the new row

  • Schema name

  • If the event was part of a snapshot (always false for delete events)

  • ID of the transaction in which the operation was performed

  • Offset of the operation in the database log

  • Timestamp for when the change was made in the database

2

op

Mandatory string that describes the type of operation. The op field value is t, signifying that this table was truncated.

3

ts_ms

Optional field that displays the time at which the connector processed the event. The time is based on the system clock in the JVM running the Kafka Connect task.

In the source object, ts_ms indicates the time that the change was made in the database. By comparing the value for payload.source.ts_ms with the value for payload.ts_ms, you can determine the lag between the source database update and Debezium.

In case a single TRUNCATE statement applies to multiple tables, one truncate change event record for each truncated table will be emitted.

Note that since truncate events represent a change made to an entire table and don’t have a message key, unless you’re working with topics with a single partition, there are no ordering guarantees for the change events pertaining to a table (create, update, etc.) and truncate events for that table. For instance a consumer may receive an update event only after a truncate event for that table, when those events are read from different partitions.

message events

This event type is only supported through the pgoutput plugin on Postgres 14+ (Postgres Documentation)

A message event signals that a generic logical decoding message has been inserted directly into the WAL typically with the pg_logical_emit_message function. The message key is a Struct with a single field named prefix in this case, carrying the prefix specified when inserting the message. The message value looks like this for transactional messages:

  1. {
  2. "schema": { ... },
  3. "payload": {
  4. "source": { (1)
  5. "version": "2.4.1.Final",
  6. "connector": "postgresql",
  7. "name": "PostgreSQL_server",
  8. "ts_ms": 1559033904863,
  9. "snapshot": false,
  10. "db": "postgres",
  11. "schema": "",
  12. "table": "",
  13. "txId": 556,
  14. "lsn": 46523128,
  15. "xmin": null
  16. },
  17. "op": "m", (2)
  18. "ts_ms": 1559033904961, (3)
  19. "message": { (4)
  20. "prefix": "foo",
  21. "content": "Ymfy"
  22. }
  23. }
  24. }

Unlike other event types, non-transactional messages will not have any associated BEGIN or END transaction events. The message value looks like this for non-transactional messages:

  1. {
  2. "schema": { ... },
  3. "payload": {
  4. "source": { (1)
  5. "version": "2.4.1.Final",
  6. "connector": "postgresql",
  7. "name": "PostgreSQL_server",
  8. "ts_ms": 1559033904863,
  9. "snapshot": false,
  10. "db": "postgres",
  11. "schema": "",
  12. "table": "",
  13. "lsn": 46523128,
  14. "xmin": null
  15. },
  16. "op": "m", (2)
  17. "ts_ms": 1559033904961 (3)
  18. "message": { (4)
  19. "prefix": "foo",
  20. "content": "Ymfy"
  21. }
  22. }
Table 13. Descriptions of message event value fields
ItemField nameDescription

1

source

Mandatory field that describes the source metadata for the event. In a message event value, the source field structure will not have table or schema information for any message events and will only have txId if the message event is transactional.

  • Debezium version

  • Connector type and name

  • Database name

  • Schema name (always “” for message events)

  • Table name (always “” for message events)

  • If the event was part of a snapshot (always false for message events)

  • ID of the transaction in which the operation was performed (null for non-transactional message events)

  • Offset of the operation in the database log

  • Transactional messages: Timestamp for when the message was inserted into the WAL

  • Non-Transactional messages; Timestamp for when the connector encounters the message

2

op

Mandatory string that describes the type of operation. The op field value is m, signifying that this is a message event.

3

ts_ms

Optional field that displays the time at which the connector processed the event. The time is based on the system clock in the JVM running the Kafka Connect task.

For transactional message events, the ts_ms attribute of the source object indicates the time that the change was made in the database for transactional message events. By comparing the value for payload.source.ts_ms with the value for payload.ts_ms, you can determine the lag between the source database update and Debezium.

For non-transactional message events, the source object’s ts_ms indicates time at which the connector encounters the message event, while the payload.ts_ms indicates the time at which the connector processed the event. This difference is due to the fact that the commit timestamp is not present in Postgres’s generic logical message format and non-transactional logical messages are not preceded by a BEGIN event (which has timestamp information).

4

message

Field that contains the message metadata

Data type mappings

The PostgreSQL connector represents changes to rows with events that are structured like the table in which the row exists. The event contains a field for each column value. How that value is represented in the event depends on the PostgreSQL data type of the column. The following sections describe how the connector maps PostgreSQL data types to a literal type and a semantic type in event fields.

  • literal type describes how the value is literally represented using Kafka Connect schema types: INT8, INT16, INT32, INT64, FLOAT32, FLOAT64, BOOLEAN, STRING, BYTES, ARRAY, MAP, and STRUCT.

  • semantic type describes how the Kafka Connect schema captures the meaning of the field using the name of the Kafka Connect schema for the field.

If the default data type conversions do not meet your needs, you can create a custom converter for the connector.

Basic types

The following table describes how the connector maps basic types.

Table 14. Mappings for PostgreSQL basic data types
PostgreSQL data typeLiteral type (schema type)Semantic type (schema name) and Notes

BOOLEAN

BOOLEAN

n/a

BIT(1)

BOOLEAN

n/a

BIT( > 1)

BYTES

io.debezium.data.Bits

The length schema parameter contains an integer that represents the number of bits. The resulting byte[] contains the bits in little-endian form and is sized to contain the specified number of bits. For example, numBytes = n/8 + (n % 8 == 0 ? 0 : 1) where n is the number of bits.

BIT VARYING[(M)]

BYTES

io.debezium.data.Bits

The length schema parameter contains an integer that represents the number of bits (2^31 - 1 in case no length is given for the column). The resulting byte[] contains the bits in little-endian form and is sized based on the content. The specified size (M) is stored in the length parameter of the io.debezium.data.Bits type.

SMALLINT, SMALLSERIAL

INT16

n/a

INTEGER, SERIAL

INT32

n/a

BIGINT, BIGSERIAL, OID

INT64

n/a

REAL

FLOAT32

n/a

DOUBLE PRECISION

FLOAT64

n/a

CHAR[(M)]

STRING

n/a

VARCHAR[(M)]

STRING

n/a

CHARACTER[(M)]

STRING

n/a

CHARACTER VARYING[(M)]

STRING

n/a

TIMESTAMPTZ, TIMESTAMP WITH TIME ZONE

STRING

io.debezium.time.ZonedTimestamp

A string representation of a timestamp with timezone information, where the timezone is GMT.

TIMETZ, TIME WITH TIME ZONE

STRING

io.debezium.time.ZonedTime

A string representation of a time value with timezone information, where the timezone is GMT.

INTERVAL [P]

INT64

io.debezium.time.MicroDuration
(default)

The approximate number of microseconds for a time interval using the 365.25 / 12.0 formula for days per month average.

INTERVAL [P]

STRING

io.debezium.time.Interval
(when interval.handling.mode is set to string)

The string representation of the interval value that follows the pattern P<years>Y<months>M<days>DT<hours>H<minutes>M<seconds>S, for example, P1Y2M3DT4H5M6.78S.

BYTEA

BYTES or STRING

n/a

Either the raw bytes (the default), a base64-encoded string, or a base64-url-safe-encoded String, or a hex-encoded string, based on the connector’s binary handling mode setting.

Debezium only supports Postgres bytea_output configuration of value hex. For more information about PostgreSQL binary data types, see the PostgreSQL documentation.

JSON, JSONB

STRING

io.debezium.data.Json

Contains the string representation of a JSON document, array, or scalar.

XML

STRING

io.debezium.data.Xml

Contains the string representation of an XML document.

UUID

STRING

io.debezium.data.Uuid

Contains the string representation of a PostgreSQL UUID value.

POINT

STRUCT

io.debezium.data.geometry.Point

Contains a structure with two FLOAT64 fields, (x,y). Each field represents the coordinates of a geometric point.

LTREE

STRING

io.debezium.data.Ltree

Contains the string representation of a PostgreSQL LTREE value.

CITEXT

STRING

n/a

INET

STRING

n/a

INT4RANGE

STRING

n/a

Range of integer.

INT8RANGE

STRING

n/a

Range of bigint.

NUMRANGE

STRING

n/a

Range of numeric.

TSRANGE

STRING

n/a

Contains the string representation of a timestamp range without a time zone.

TSTZRANGE

STRING

n/a

Contains the string representation of a timestamp range with the local system time zone.

DATERANGE

STRING

n/a

Contains the string representation of a date range. It always has an exclusive upper-bound.

ENUM

STRING

io.debezium.data.Enum

Contains the string representation of the PostgreSQL ENUM value. The set of allowed values is maintained in the allowed schema parameter.

Temporal types

Other than PostgreSQL’s TIMESTAMPTZ and TIMETZ data types, which contain time zone information, how temporal types are mapped depends on the value of the time.precision.mode connector configuration property. The following sections describe these mappings:

time.precision.mode=adaptive

When the time.precision.mode property is set to adaptive, the default, the connector determines the literal type and semantic type based on the column’s data type definition. This ensures that events exactly represent the values in the database.

Table 15. Mappings when time.precision.mode is adaptive
PostgreSQL data typeLiteral type (schema type)Semantic type (schema name) and Notes

DATE

INT32

io.debezium.time.Date

Represents the number of days since the epoch.

TIME(1), TIME(2), TIME(3)

INT32

io.debezium.time.Time

Represents the number of milliseconds past midnight, and does not include timezone information.

TIME(4), TIME(5), TIME(6)

INT64

io.debezium.time.MicroTime

Represents the number of microseconds past midnight, and does not include timezone information.

TIMESTAMP(1), TIMESTAMP(2), TIMESTAMP(3)

INT64

io.debezium.time.Timestamp

Represents the number of milliseconds since the epoch, and does not include timezone information.

TIMESTAMP(4), TIMESTAMP(5), TIMESTAMP(6), TIMESTAMP

INT64

io.debezium.time.MicroTimestamp

Represents the number of microseconds since the epoch, and does not include timezone information.

time.precision.mode=adaptive_time_microseconds

When the time.precision.mode configuration property is set to adaptive_time_microseconds, the connector determines the literal type and semantic type for temporal types based on the column’s data type definition. This ensures that events exactly represent the values in the database, except all TIME fields are captured as microseconds.

Table 16. Mappings when time.precision.mode is adaptive_time_microseconds
PostgreSQL data typeLiteral type (schema type)Semantic type (schema name) and Notes

DATE

INT32

io.debezium.time.Date

Represents the number of days since the epoch.

TIME([P])

INT64

io.debezium.time.MicroTime

Represents the time value in microseconds and does not include timezone information. PostgreSQL allows precision P to be in the range 0-6 to store up to microsecond precision.

TIMESTAMP(1) , TIMESTAMP(2), TIMESTAMP(3)

INT64

io.debezium.time.Timestamp

Represents the number of milliseconds past the epoch, and does not include timezone information.

TIMESTAMP(4) , TIMESTAMP(5), TIMESTAMP(6), TIMESTAMP

INT64

io.debezium.time.MicroTimestamp

Represents the number of microseconds past the epoch, and does not include timezone information.

time.precision.mode=connect

When the time.precision.mode configuration property is set to connect, the connector uses Kafka Connect logical types. This may be useful when consumers can handle only the built-in Kafka Connect logical types and are unable to handle variable-precision time values. However, since PostgreSQL supports microsecond precision, the events generated by a connector with the connect time precision mode results in a loss of precision when the database column has a fractional second precision value that is greater than 3.

Table 17. Mappings when time.precision.mode is connect
PostgreSQL data typeLiteral type (schema type)Semantic type (schema name) and Notes

DATE

INT32

org.apache.kafka.connect.data.Date

Represents the number of days since the epoch.

TIME([P])

INT64

org.apache.kafka.connect.data.Time

Represents the number of milliseconds since midnight, and does not include timezone information. PostgreSQL allows P to be in the range 0-6 to store up to microsecond precision, though this mode results in a loss of precision when P is greater than 3.

TIMESTAMP([P])

INT64

org.apache.kafka.connect.data.Timestamp

Represents the number of milliseconds since the epoch, and does not include timezone information. PostgreSQL allows P to be in the range 0-6 to store up to microsecond precision, though this mode results in a loss of precision when P is greater than 3.

TIMESTAMP type

The TIMESTAMP type represents a timestamp without time zone information. Such columns are converted into an equivalent Kafka Connect value based on UTC. For example, the TIMESTAMP value “2018-06-20 15:13:16.945104” is represented by an io.debezium.time.MicroTimestamp with the value “1529507596945104” when time.precision.mode is not set to connect.

The timezone of the JVM running Kafka Connect and Debezium does not affect this conversion.

PostgreSQL supports using +/-infinite values in TIMESTAMP columns. These special values are converted to timestamps with value 9223372036825200000 in case of positive infinity or -9223372036832400000 in case of negative infinity. This behavior mimics the standard behavior of the PostgreSQL JDBC driver. For reference, see the org.postgresql.PGStatement interface.

Decimal types

The setting of the PostgreSQL connector configuration property decimal.handling.mode determines how the connector maps decimal types.

When the decimal.handling.mode property is set to precise, the connector uses the Kafka Connect org.apache.kafka.connect.data.Decimal logical type for all DECIMAL, NUMERIC and MONEY columns. This is the default mode.

Table 18. Mappings when decimal.handling.mode is precise
PostgreSQL data typeLiteral type (schema type)Semantic type (schema name) and Notes

NUMERIC[(M[,D])]

BYTES

org.apache.kafka.connect.data.Decimal

The scale schema parameter contains an integer representing how many digits the decimal point was shifted.

DECIMAL[(M[,D])]

BYTES

org.apache.kafka.connect.data.Decimal

The scale schema parameter contains an integer representing how many digits the decimal point was shifted.

MONEY[(M[,D])]

BYTES

org.apache.kafka.connect.data.Decimal

The scale schema parameter contains an integer representing how many digits the decimal point was shifted. The scale schema parameter is determined by the money.fraction.digits connector configuration property.

There is an exception to this rule. When the NUMERIC or DECIMAL types are used without scale constraints, the values coming from the database have a different (variable) scale for each value. In this case, the connector uses io.debezium.data.VariableScaleDecimal, which contains both the value and the scale of the transferred value.

Table 19. Mappings of DECIMAL and NUMERIC types when there are no scale constraints
PostgreSQL data typeLiteral type (schema type)Semantic type (schema name) and Notes

NUMERIC

STRUCT

io.debezium.data.VariableScaleDecimal

Contains a structure with two fields: scale of type INT32 that contains the scale of the transferred value and value of type BYTES containing the original value in an unscaled form.

DECIMAL

STRUCT

io.debezium.data.VariableScaleDecimal

Contains a structure with two fields: scale of type INT32 that contains the scale of the transferred value and value of type BYTES containing the original value in an unscaled form.

When the decimal.handling.mode property is set to double, the connector represents all DECIMAL, NUMERIC and MONEY values as Java double values and encodes them as shown in the following table.

Table 20. Mappings when decimal.handling.mode is double
PostgreSQL data typeLiteral type (schema type)Semantic type (schema name)

NUMERIC[(M[,D])]

FLOAT64

DECIMAL[(M[,D])]

FLOAT64

MONEY[(M[,D])]

FLOAT64

The last possible setting for the decimal.handling.mode configuration property is string. In this case, the connector represents DECIMAL, NUMERIC and MONEY values as their formatted string representation, and encodes them as shown in the following table.

Table 21. Mappings when decimal.handling.mode is string
PostgreSQL data typeLiteral type (schema type)Semantic type (schema name)

NUMERIC[(M[,D])]

STRING

DECIMAL[(M[,D])]

STRING

MONEY[(M[,D])]

STRING

PostgreSQL supports NaN (not a number) as a special value to be stored in DECIMAL/NUMERIC values when the setting of decimal.handling.mode is string or double. In this case, the connector encodes NaN as either Double.NaN or the string constant NAN.

HSTORE type

The setting of the PostgreSQL connector configuration property hstore.handling.mode determines how the connector maps HSTORE values.

When the dhstore.handling.mode property is set to json (the default), the connector represents HSTORE values as string representations of JSON values and encodes them as shown in the following table. When the hstore.handling.mode property is set to map, the connector uses the MAP schema type for HSTORE values.

Table 22. Mappings for HSTORE data type
PostgreSQL data typeLiteral type (schema type)Semantic type (schema name) and Notes

HSTORE

STRING

io.debezium.data.Json

Example: output representation using the JSON converter is {“key” : “val”}

HSTORE

MAP

n/a

Example: output representation using the JSON converter is {“key” : “val”}

Domain types

PostgreSQL supports user-defined types that are based on other underlying types. When such column types are used, Debezium exposes the column’s representation based on the full type hierarchy.

Capturing changes in columns that use PostgreSQL domain types requires special consideration. When a column is defined to contain a domain type that extends one of the default database types and the domain type defines a custom length or scale, the generated schema inherits that defined length or scale.

When a column is defined to contain a domain type that extends another domain type that defines a custom length or scale, the generated schema does not inherit the defined length or scale because that information is not available in the PostgreSQL driver’s column metadata.

Network address types

PostgreSQL has data types that can store IPv4, IPv6, and MAC addresses. It is better to use these types instead of plain text types to store network addresses. Network address types offer input error checking and specialized operators and functions.

Table 23. Mappings for network address types
PostgreSQL data typeLiteral type (schema type)Semantic type (schema name) and Notes

INET

STRING

n/a

IPv4 and IPv6 networks

CIDR

STRING

n/a

IPv4 and IPv6 hosts and networks

MACADDR

STRING

n/a

MAC addresses

MACADDR8

STRING

n/a

MAC addresses in EUI-64 format

PostGIS types

The PostgreSQL connector supports all PostGIS data types.

Table 24. Mappings of PostGIS data types
PostGIS data typeLiteral type (schema type)Semantic type (schema name) and Notes

GEOMETRY
(planar)

STRUCT

io.debezium.data.geometry.Geometry

Contains a structure with two fields:

  • srid (INT32) - Spatial Reference System Identifier that defines what type of geometry object is stored in the structure.

  • wkb (BYTES) - A binary representation of the geometry object encoded in the Well-Known-Binary format.

GEOGRAPHY
(spherical)

STRUCT

io.debezium.data.geometry.Geography

Contains a structure with two fields:

  • srid (INT32) - Spatial Reference System Identifier that defines what type of geography object is stored in the structure.

  • wkb (BYTES) - A binary representation of the geometry object encoded in the Well-Known-Binary format.

Toasted values

PostgreSQL has a hard limit on the page size. This means that values that are larger than around 8 KBs need to be stored by using TOAST storage. This impacts replication messages that are coming from the database. Values that were stored by using the TOAST mechanism and that have not been changed are not included in the message, unless they are part of the table’s replica identity. There is no safe way for Debezium to read the missing value out-of-bands directly from the database, as this would potentially lead to race conditions. Consequently, Debezium follows these rules to handle toasted values:

  • Tables with REPLICA IDENTITY FULL - TOAST column values are part of the before and after fields in change events just like any other column.

  • Tables with REPLICA IDENTITY DEFAULT - When receiving an UPDATE event from the database, any unchanged TOAST column value that is not part of the replica identity is not contained in the event. Similarly, when receiving a DELETE event, no TOAST columns, if any, are in the before field. As Debezium cannot safely provide the column value in this case, the connector returns a placeholder value as defined by the connector configuration property, unavailable.value.placeholder.

Default values

If a default value is specified for a column in the database schema, the PostgreSQL connector will attempt to propagate this value to the Kafka schema whenever possible. Most common data types are supported, including:

  • BOOLEAN

  • Numeric types (INT, FLOAT, NUMERIC, etc.)

  • Text types (CHAR, VARCHAR, TEXT, etc.)

  • Temporal types (DATE, TIME, INTERVAL, TIMESTAMP, TIMESTAMPTZ)

  • JSON, JSONB, XML

  • UUID

Note that for temporal types, parsing of the default value is provided by PostgreSQL libraries; therefore, any string representation which is normally supported by PostgreSQL should also be supported by the connector.

In the case that the default value is generated by a function rather than being directly specified in-line, the connector will instead export the equivalent of 0 for the given data type. These values include:

  • FALSE for BOOLEAN

  • 0 with appropriate precision, for numeric types

  • Empty string for text/XML types

  • {} for JSON types

  • 1970-01-01 for DATE, TIMESTAMP, TIMESTAMPTZ types

  • 00:00 for TIME

  • EPOCH for INTERVAL

  • 00000000-0000-0000-0000-000000000000 for UUID

This support currently extends only to explicit usage of functions. For example, CURRENT_TIMESTAMP(6) is supported with parentheses, but CURRENT_TIMESTAMP is not.

Support for the propagation of default values exists primarily to allow for safe schema evolution when using the PostgreSQL connector with a schema registry which enforces compatibility between schema versions. Due to this primary concern, as well as the refresh behaviours of the different plug-ins, the default value present in the Kafka schema is not guaranteed to always be in-sync with the default value in the database schema.

  • Default values may appear ‘late’ in the Kafka schema, depending on when/how a given plugin triggers refresh of the in-memory schema. Values may never appear/be skipped in the Kafka schema if the default changes multiple times in-between refreshes

  • Default values may appear ‘early’ in the Kafka schema, if a schema refresh is triggered while the connector has records waiting to be processed. This is due to the column metadata being read from the database at refresh time, rather than being present in the replication message. This may occur if the connector is behind and a refresh occurs, or on connector start if the connector was stopped for a time while updates continued to be written to the source database.

This behaviour may be unexpected, but it is still safe. Only the schema definition is affected, while the real values present in the message will remain consistent with what was written to the source database.

Setting up Postgres

Before using the PostgreSQL connector to monitor the changes committed on a PostgreSQL server, decide which logical decoding plug-in you intend to use. If you plan not to use the native pgoutput logical replication stream support, then you must install the logical decoding plug-in into the PostgreSQL server. Afterward, enable a replication slot, and configure a user with sufficient privileges to perform the replication.

If your database is hosted by a service such as Heroku Postgres you might be unable to install the plug-in. If so, and if you are using PostgreSQL 10+, you can use the pgoutput decoder support to capture changes in your database. If that is not an option, you are unable to use Debezium with your database.

PostgreSQL in the Cloud

PostgreSQL on Amazon RDS

It is possible to capture changes in a PostgreSQL database that is running in Amazon RDS. To do this:

  • Set the instance parameter rds.logical_replication to 1.

  • Verify that the wal_level parameter is set to logical by running the query SHOW wal_level as the database RDS master user. This might not be the case in multi-zone replication setups. You cannot set this option manually. It is automatically changed when the rds.logical_replication parameter is set to 1. If the wal_level is not set to logical after you make the preceding change, it is probably because the instance has to be restarted after the parameter group change. Restarts occur during your maintenance window, or you can initiate a restart manually.

  • Set the Debezium plugin.name parameter to pgoutput.

  • Initiate logical replication from an AWS account that has the rds_replication role. The role grants permissions to manage logical slots and to stream data using logical slots. By default, only the master user account on AWS has the rds_replication role on Amazon RDS. To enable a user account other than the master account to initiate logical replication, you must grant the account the rds_replication role. For example, grant rds_replication to _<my_user>_. You must have superuser access to grant the rds_replication role to a user. To enable accounts other than the master account to create an initial snapshot, you must grant SELECT permission to the accounts on the tables to be captured. For more information about security for PostgreSQL logical replication, see the PostgreSQL documentation.

PostgreSQL on Azure

It is possible to use Debezium with Azure Database for PostgreSQL, which has support for the pgoutput logical decoding plug-in, which is supported by Debezium.

Set the Azure replication support to logical. You can use the Azure CLI or the Azure Portal to configure this. For example, to use the Azure CLI, here are the az postgres server commands that you need to execute:

  1. az postgres server configuration set --resource-group mygroup --server-name myserver --name azure.replication_support --value logical
  2. az postgres server restart --resource-group mygroup --name myserver

PostgreSQL on CrunchyBridge

It is possible to use Debezium with CrunchyBridge; logical replication is already turned on. The pgoutput plugin is available. You will have to create a replication user and provide correct privileges.

While using the pgoutput plug-in, it is recommended that you configure filtered as the publication.autocreate.mode. If you use all_tables, which is the default value for publication.autocreate.mode, and the publication is not found, the connector tries to create one by using CREATE PUBLICATION <publication_name> FOR ALL TABLES;, but this fails due to lack of permissions.

Installing the logical decoding output plug-in

For more detailed instructions about setting up and testing logical decoding plug-ins, see Logical Decoding Output Plug-in Installation for PostgreSQL .

As of PostgreSQL 9.4, the only way to read changes to the write-ahead-log is to install a logical decoding output plug-in. Plug-ins are written in C, compiled, and installed on the machine that runs the PostgreSQL server. Plug-ins use a number of PostgreSQL specific APIs, as described by the PostgreSQL documentation.

The PostgreSQL connector works with one of Debezium’s supported logical decoding plug-ins to receive change events from the database in either the Protobuf format or the pgoutput format. The pgoutput plugin comes out-of-the-box with the PostgreSQL database. For more details on using Protobuf via the decoderbufs plug-in, see the plug-in documentation which discusses its requirements, limitations, and how to compile it.

For simplicity, Debezium also provides a container image based on the upstream PostgreSQL server image, on top of which it compiles and installs the plug-ins. You can use this image as an example of the detailed steps required for the installation.

The Debezium logical decoding plug-ins have been installed and tested on only Linux machines. For Windows and other operating systems, different installation steps might be required.

Plug-in differences

Plug-in behavior is not completely the same for all cases. These differences have been identified:

  • While all plug-ins will refresh schema metadata from the database upon detection of a schema change during streaming, the pgoutput plug-in is somewhat more ‘eager’ about triggering such refreshes. For example, a change to the default value for a column will trigger a refresh with pgoutput, while other plug-ins will not be aware of this change until another change triggers a refresh (eg. addition of a new column.) This is due to the behaviour of pgoutput, rather than Debezium itself.

All up-to-date differences are tracked in a test suite Java class.

Configuring the PostgreSQL server

If you are using a logical decoding plug-in other than pgoutput, after installing it, configure the PostgreSQL server as follows:

  1. To load the plug-in at startup, add the following to the postgresql.conf file::

    1. # MODULES
    2. shared_preload_libraries = 'decoderbufs' (1)
    1Instructs the server to load the decoderbufs logical decoding plug-ins at startup (the name of the plug-in is set in the Protobuf make file).
  2. To configure the replication slot regardless of the decoder being used, specify the following in the postgresql.conf file:

    1. # REPLICATION
    2. wal_level = logical (1)
    1Instructs the server to use logical decoding with the write-ahead log.

Depending on your requirements, you may have to set other PostgreSQL streaming replication parameters when using Debezium. Examples include max_wal_senders and max_replication_slots for increasing the number of connectors that can access the sending server concurrently, and wal_keep_size for limiting the maximum WAL size which a replication slot will retain. For more information about configuring streaming replication, see the PostgreSQL documentation.

Debezium uses PostgreSQL’s logical decoding, which uses replication slots. Replication slots are guaranteed to retain all WAL segments required for Debezium even during Debezium outages. For this reason, it is important to closely monitor replication slots to avoid too much disk consumption and other conditions that can happen such as catalog bloat if a replication slot stays unused for too long. For more information, see the PostgreSQL streaming replication documentation.

If you are working with a synchronous_commit setting other than on, the recommendation is to set wal_writer_delay to a value such as 10 milliseconds to achieve a low latency of change events. Otherwise, its default value is applied, which adds a latency of about 200 milliseconds.

Setting up permissions

Setting up a PostgreSQL server to run a Debezium connector requires a database user that can perform replications. Replication can be performed only by a database user that has appropriate permissions and only for a configured number of hosts.

Although, by default, superusers have the necessary REPLICATION and LOGIN roles, as mentioned in Security, it is best not to provide the Debezium replication user with elevated privileges. Instead, create a Debezium user that has the minimum required privileges.

Prerequisites

  • PostgreSQL administrative permissions.

Procedure

  1. To provide a user with replication permissions, define a PostgreSQL role that has at least the REPLICATION and LOGIN permissions, and then grant that role to the user. For example:

    1. CREATE ROLE <name> REPLICATION LOGIN;

Setting privileges to enable Debezium to create PostgreSQL publications when you use pgoutput

If you use pgoutput as the logical decoding plugin, Debezium must operate in the database as a user with specific privileges.

Debezium streams change events for PostgreSQL source tables from publications that are created for the tables. Publications contain a filtered set of change events that are generated from one or more tables. The data in each publication is filtered based on the publication specification. The specification can be created by the PostgreSQL database administrator or by the Debezium connector. To permit the Debezium PostgreSQL connector to create publications and specify the data to replicate to them, the connector must operate with specific privileges in the database.

There are several options for determining how publications are created. In general, it is best to manually create publications for the tables that you want to capture, before you set up the connector. However, you can configure your environment in a way that permits Debezium to create publications automatically, and to specify the data that is added to them.

Debezium uses include list and exclude list properties to specify how data is inserted in the publication. For more information about the options for enabling Debezium to create publications, see publication.autocreate.mode.

For Debezium to create a PostgreSQL publication, it must run as a user that has the following privileges:

  • Replication privileges in the database to add the table to a publication.

  • CREATE privileges on the database to add publications.

  • SELECT privileges on the tables to copy the initial table data. Table owners automatically have SELECT permission for the table.

To add tables to a publication, the user must be an owner of the table. But because the source table already exists, you need a mechanism to share ownership with the original owner. To enable shared ownership, you create a PostgreSQL replication group, and then add the existing table owner and the replication user to the group.

Procedure

  1. Create a replication group.

    1. CREATE ROLE <replication_group>;
  2. Add the original owner of the table to the group.

    1. GRANT REPLICATION_GROUP TO <original_owner>;
  3. Add the Debezium replication user to the group.

    1. GRANT REPLICATION_GROUP TO <replication_user>;
  4. Transfer ownership of the table to <replication_group>.

    1. ALTER TABLE <table_name> OWNER TO REPLICATION_GROUP;

For Debezium to specify the capture configuration, the value of publication.autocreate.mode must be set to filtered.

Configuring PostgreSQL to allow replication with the Debezium connector host

To enable Debezium to replicate PostgreSQL data, you must configure the database to permit replication with the host that runs the PostgreSQL connector. To specify the clients that are permitted to replicate with the database, add entries to the PostgreSQL host-based authentication file, pg_hba.conf. For more information about the pg_hba.conf file, see the PostgreSQL documentation.

Procedure

  • Add entries to the pg_hba.conf file to specify the Debezium connector hosts that can replicate with the database host. For example,

    pg_hba.conf file example:

    1. local replication <youruser> trust (1)
    2. host replication <youruser> 127.0.0.1/32 trust (2)
    3. host replication <youruser> ::1/128 trust (3)
    1Instructs the server to allow replication for <youruser> locally, that is, on the server machine.
    2Instructs the server to allow <youruser> on localhost to receive replication changes using IPV4.
    3Instructs the server to allow <youruser> on localhost to receive replication changes using IPV6.

For more information about network masks, see the PostgreSQL documentation.

Supported PostgreSQL topologies

The PostgreSQL connector can be used with a standalone PostgreSQL server or with a cluster of PostgreSQL servers.

As mentioned in the beginning, PostgreSQL (for all versions ⇐ 12) supports logical replication slots on only primary servers. This means that a replica in a PostgreSQL cluster cannot be configured for logical replication, and consequently that the Debezium PostgreSQL connector can connect and communicate with only the primary server. Should this server fail, the connector stops. When the cluster is repaired, if the original primary server is once again promoted to primary, you can restart the connector. However, if a different PostgreSQL server with the plug-in and proper configuration is promoted to primary, you must change the connector configuration to point to the new primary server and then you can restart the connector.

WAL disk space consumption

In certain cases, it is possible for PostgreSQL disk space consumed by WAL files to spike or increase out of usual proportions. There are several possible reasons for this situation:

  • The LSN up to which the connector has received data is available in the confirmed_flush_lsn column of the server’s pg_replication_slots view. Data that is older than this LSN is no longer available, and the database is responsible for reclaiming the disk space.

    Also in the pg_replication_slots view, the restart_lsn column contains the LSN of the oldest WAL that the connector might require. If the value for confirmed_flush_lsn is regularly increasing and the value of restart_lsn lags then the database needs to reclaim the space.

    The database typically reclaims disk space in batch blocks. This is expected behavior and no action by a user is necessary.

  • There are many updates in a database that is being tracked but only a tiny number of updates are related to the table(s) and schema(s) for which the connector is capturing changes. This situation can be easily solved with periodic heartbeat events. Set the heartbeat.interval.ms connector configuration property.

    For the connector to detect and process events from a heartbeat table, you must add the table to the PostgreSQL publication specified by the publication.name property. If this publication predates your Debezium deployment, the connector uses the publications as defined. If the publication is not already configured to automatically replicate changes FOR ALL TABLES in the database, you must explicitly add the heartbeat table to the publication, for example,

    ALTER PUBLICATION <publicationName> ADD TABLE <heartbeatTableName>;

  • The PostgreSQL instance contains multiple databases and one of them is a high-traffic database. Debezium captures changes in another database that is low-traffic in comparison to the other database. Debezium then cannot confirm the LSN as replication slots work per-database and Debezium is not invoked. As WAL is shared by all databases, the amount used tends to grow until an event is emitted by the database for which Debezium is capturing changes. To overcome this, it is necessary to:

    • Enable periodic heartbeat record generation with the heartbeat.interval.ms connector configuration property.

    • Regularly emit change events from the database for which Debezium is capturing changes.

    A separate process would then periodically update the table by either inserting a new row or repeatedly updating the same row. PostgreSQL then invokes Debezium, which confirms the latest LSN and allows the database to reclaim the WAL space. This task can be automated by means of the heartbeat.action.query connector configuration property.

For users on AWS RDS with PostgreSQL, a situation similar to the high traffic/low traffic scenario can occur in an idle environment. AWS RDS causes writes to its own system tables to be invisible to clients on a frequent basis (5 minutes). Again, regularly emitting events solves the problem.

Setting up multiple connectors for same database server

Debezium uses replication slots to stream changes from a database. These replication slots maintain the current position in form of a LSN (Log Sequence Number) which is pointer to a location in the WAL being consumed by the Debezium connector. This helps PostgreSQL keep the WAL available until it is processed by Debezium. A single replication slot can exist only for a single consumer or process - as different consumer might have different state and may need data from different position.

Since a replication slot can only be used by a single connector, it is essential to create a unique replication slot for each Debezium connector. Although when a connector is not active, Postgres may allow other connector to consume the replication slot - which could be dangerous as it may lead to data loss as a slot will emit each change just once [See More].

In addition to replication slot, Debezium uses publication to stream events when using the pgoutput plugin. Similar to replication slot, publication is at database level and is defined for a set of tables. Thus, you’ll need a unique publication for each connector, unless the connectors work on same set of tables. For more information about the options for enabling Debezium to create publications, see publication.autocreate.mode

See slot.name and publication.name on how to set a unique replication slot name and publication name for each connector.

Upgrading PostgreSQL

When you upgrade the PostgreSQL database that Debezium uses, you must take specific steps to protect against data loss and to ensure that Debezium continues to operate. In general, Debezium is resilient to interruptions caused by network failures and other outages. For example, when a database server that a connector monitors stops or crashes, after the connector re-establishes communication with the PostgreSQL server, it continues to read from the last position recorded by the log sequence number (LSN) offset. The connector retrieves information about the last recorded offset from the Kafka Connect offsets topic, and queries the configured PostgreSQL replication slot for a log sequence number (LSN) with the same value.

For the connector to start and to capture change events from a PostgreSQL database, a replication slot must be present. However, as part of the PostgreSQL upgrade process, replication slots are removed, and the original slots are not restored after the upgrade completes. As a result, when the connector restarts and requests the last known offset from the replication slot, PostgreSQL cannot return the information.

You can create a new replication slot, but you must do more than create a new slot to guard against data loss. A new replication slot can provide the LSNs only for changes the occur after you create the slot; it cannot provide the offsets for events that occurred before the upgrade. When the connector restarts, it first requests the last known offset from the Kafka offsets topic. It then sends a request to the replication slot to return information for the offset retrieved from the offsets topic. But the new replication slot cannot provide the information that the connector needs to resume streaming from the expected position. The connector then skips any existing change events in the log, and only resumes streaming from the most recent position in the log. This can lead to silent data loss: the connector emits no records for the skipped events, and it does not provide any information to indicate that events were skipped.

For guidance about how to perform a PostgreSQL database upgrade so that Debezium can continue to capture events while minimizing the risk of data loss, see the following procedure.

Procedure

  1. Temporarily stop applications that write to the database, or put them into a read-only mode.

  2. Back up the database.

  3. Temporarily disable write access to the database.

  4. Verify that any changes that occurred in the database before you blocked write operations are saved to the write-ahead log (WAL), and that the WAL LSN is reflected on the replication slot.

  5. Provide the connector with enough time to capture all event records that are written to the replication slot.
    This step ensures that all change events that occurred before the downtime are accounted for, and that they are saved to Kafka.

  6. Verify that the connector has finished consuming entries from the replication slot by checking the value of the flushed LSN.

  7. Shut down the connector gracefully by stopping Kafka Connect.
    Kafka Connect stops the connectors, flushes all event records to Kafka, and records the last offset received from each connector.

    As an alternative to stopping the entire Kafka Connect cluster, you can stop the connector by deleting it. Do not remove the offset topic, because it might be shared by other Kafka connectors. Later, after you restore write access to the database and you are ready to restart the connector, you must recreate the connector.

  8. As a PostgreSQL administrator, drop the replication slot on the primary database server. Do not use the slot.drop.on.stop property to drop the replication slot. This property is for testing only.

  9. Stop the database.

  10. Perform the upgrade using an approved PostgreSQL upgrade procedure, such as pg_upgrade, or pg_dump and pg_restore.

  11. (Optional) Use a standard Kafka tool to remove the connector offsets from the offset storage topic.
    For an example of how to remove connector offsets, see how to remove connector offsets in the Debezium community FAQ.

  12. Restart the database.

  13. As a PostgreSQL administrator, create a Debezium logical replication slot on the database. You must create the slot before enabling writes to the database. Otherwise, Debezium cannot capture the changes, resulting in data loss.

  14. Verify that the publication that defines the tables for Debezium to capture is still present after the upgrade. If the publication is not available, connect to the database as a PostgreSQL administrator to create a new publication.

  15. If it was necessary to create a new publication in the previous step, update the Debezium connector configuration to add the name of the new publication to the publication.name property.

  16. In the connector configuration, rename the connector.

  17. In the connector configuration, set slot.name to the name of the Debezium replication slot.

  18. Verify that the new replication slot is available.

  19. Restore write access to the database and restart any applications that write to the database.

  20. In the connector configuration, set the snapshot.mode property to never, and then restart the connector.

    If you were unable to verify that Debezium finished reading all database changes in Step 6, you can configure the connector to perform a new snapshot by setting snapshot.mode=initial. If necessary, you can confirm whether the connector read all changes from the replication slot by checking the contents of a database backup that was taken immediately before the upgrade.

Additional resources

Deployment

To deploy a Debezium PostgreSQL connector, you install the Debezium PostgreSQL connector archive, configure the connector, and start the connector by adding its configuration to Kafka Connect.

Prerequisites

Procedure

  1. Download the Debezium PostgreSQL connector plug-in archive.

  2. Extract the files into your Kafka Connect environment.

  3. Add the directory with the JAR files to Kafka Connect’s plugin.path.

  4. Restart your Kafka Connect process to pick up the new JAR files.

If you are working with immutable containers, see Debezium’s Container images for Zookeeper, Kafka, PostgreSQL and Kafka Connect with the PostgreSQL connector already installed and ready to run. You can also run Debezium on Kubernetes and OpenShift.

Connector configuration example

Following is an example of the configuration for a PostgreSQL connector that connects to a PostgreSQL server on port 5432 at 192.168.99.100, whose logical name is fulfillment. Typically, you configure the Debezium PostgreSQL connector in a JSON file by setting the configuration properties available for the connector.

You can choose to produce events for a subset of the schemas and tables in a database. Optionally, you can ignore, mask, or truncate columns that contain sensitive data, are larger than a specified size, or that you do not need.

  1. {
  2. "name": "fulfillment-connector", (1)
  3. "config": {
  4. "connector.class": "io.debezium.connector.postgresql.PostgresConnector", (2)
  5. "database.hostname": "192.168.99.100", (3)
  6. "database.port": "5432", (4)
  7. "database.user": "postgres", (5)
  8. "database.password": "postgres", (6)
  9. "database.dbname" : "postgres", (7)
  10. "topic.prefix": "fulfillment", (8)
  11. "table.include.list": "public.inventory" (9)
  12. }
  13. }
1The name of the connector when registered with a Kafka Connect service.
2The name of this PostgreSQL connector class.
3The address of the PostgreSQL server.
4The port number of the PostgreSQL server.
5The name of the PostgreSQL user that has the required privileges.
6The password for the PostgreSQL user that has the required privileges.
7The name of the PostgreSQL database to connect to
8The topic prefix for the PostgreSQL server/cluster, which forms a namespace and is used in all the names of the Kafka topics to which the connector writes, the Kafka Connect schema names, and the namespaces of the corresponding Avro schema when the Avro converter is used.
9A list of all tables hosted by this server that this connector will monitor. This is optional, and there are other properties for listing the schemas and tables to include or exclude from monitoring.

See the complete list of PostgreSQL connector properties that can be specified in these configurations.

You can send this configuration with a POST command to a running Kafka Connect service. The service records the configuration and starts one connector task that performs the following actions:

  • Connects to the PostgreSQL database.

  • Reads the transaction log.

  • Streams change event records to Kafka topics.

Adding connector configuration

To run a Debezium PostgreSQL connector, create a connector configuration and add the configuration to your Kafka Connect cluster.

Prerequisites

Procedure

  1. Create a configuration for the PostgreSQL connector.

  2. Use the Kafka Connect REST API to add that connector configuration to your Kafka Connect cluster.

Results

After the connector starts, it performs a consistent snapshot of the PostgreSQL server databases that the connector is configured for. The connector then starts generating data change events for row-level operations and streaming change event records to Kafka topics.

Connector properties

The Debezium PostgreSQL connector has many configuration properties that you can use to achieve the right connector behavior for your application. Many properties have default values. Information about the properties is organized as follows:

The following configuration properties are required unless a default value is available.

Table 25. Required connector configuration properties
PropertyDefaultDescription

No default

Unique name for the connector. Attempting to register again with the same name will fail. This property is required by all Kafka Connect connectors.

No default

The name of the Java class for the connector. Always use a value of io.debezium.connector.postgresql.PostgresConnector for the PostgreSQL connector.

1

The maximum number of tasks that should be created for this connector. The PostgreSQL connector always uses a single task and therefore does not use this value, so the default is always acceptable.

decoderbufs

The name of the PostgreSQL logical decoding plug-in installed on the PostgreSQL server.

Supported values are decoderbufs, and pgoutput.

debezium

The name of the PostgreSQL logical decoding slot that was created for streaming changes from a particular plug-in for a particular database/schema. The server uses this slot to stream events to the Debezium connector that you are configuring.

Slot names must conform to PostgreSQL replication slot naming rules, which state: “Each replication slot has a name, which can contain lower-case letters, numbers, and the underscore character.”

false

Whether or not to delete the logical replication slot when the connector stops in a graceful, expected way. The default behavior is that the replication slot remains configured for the connector when the connector stops. When the connector restarts, having the same replication slot enables the connector to start processing where it left off.

Set to true in only testing or development environments. Dropping the slot allows the database to discard WAL segments. When the connector restarts it performs a new snapshot or it can continue from a persistent offset in the Kafka Connect offsets topic.

dbzpublication

The name of the PostgreSQL publication created for streaming changes when using pgoutput.

This publication is created at start-up if it does not already exist and it includes all tables. Debezium then applies its own include/exclude list filtering, if configured, to limit the publication to change events for the specific tables of interest. The connector user must have superuser permissions to create this publication, so it is usually preferable to create the publication before starting the connector for the first time.

If the publication already exists, either for all tables or configured with a subset of tables, Debezium uses the publication as it is defined.

No default

IP address or hostname of the PostgreSQL database server.

5432

Integer port number of the PostgreSQL database server.

No default

Name of the PostgreSQL database user for connecting to the PostgreSQL database server.

No default

Password to use when connecting to the PostgreSQL database server.

No default

The name of the PostgreSQL database from which to stream the changes.

No default

Topic prefix that provides a namespace for the particular PostgreSQL database server or cluster in which Debezium is capturing changes. The prefix should be unique across all other connectors, since it is used as a topic name prefix for all Kafka topics that receive records from this connector. Only alphanumeric characters, hyphens, dots and underscores must be used in the database server logical name.

Do not change the value of this property. If you change the name value, after a restart, instead of continuing to emit events to the original topics, the connector emits subsequent events to topics whose names are based on the new value.

No default

An optional, comma-separated list of regular expressions that match names of schemas for which you want to capture changes. Any schema name not included in schema.include.list is excluded from having its changes captured. By default, all non-system schemas have their changes captured.

To match the name of a schema, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire identifier for the schema; it does not match substrings that might be present in a schema name.
If you include this property in the configuration, do not also set the schema.exclude.list property.

No default

An optional, comma-separated list of regular expressions that match names of schemas for which you do not want to capture changes. Any schema whose name is not included in schema.exclude.list has its changes captured, with the exception of system schemas.

To match the name of a schema, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire identifier for the schema; it does not match substrings that might be present in a schema name.
If you include this property in the configuration, do not set the schema.include.list property.

No default

An optional, comma-separated list of regular expressions that match fully-qualified table identifiers for tables whose changes you want to capture. When this property is set, the connector captures changes only from the specified tables. Each identifier is of the form schemaName.tableName. By default, the connector captures changes in every non-system table in each schema whose changes are being captured.

To match the name of a table, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire identifier for the table; it does not match substrings that might be present in a table name.
If you include this property in the configuration, do not also set the table.exclude.list property.

No default

An optional, comma-separated list of regular expressions that match fully-qualified table identifiers for tables whose changes you do not want to capture. Each identifier is of the form schemaName.tableName. When this property is set, the connector captures changes from every table that you do not specify.

To match the name of a table, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire identifier for the table; it does not match substrings that might be present in a table name.
If you include this property in the configuration, do not set the table.include.list property.

No default

An optional, comma-separated list of regular expressions that match the fully-qualified names of columns that should be included in change event record values. Fully-qualified names for columns are of the form schemaName.tableName.columnName.

To match the name of a column, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the expression is used to match the entire name string of the column; it does not match substrings that might be present in a column name.
If you include this property in the configuration, do not also set the column.exclude.list property.

No default

An optional, comma-separated list of regular expressions that match the fully-qualified names of columns that should be excluded from change event record values. Fully-qualified names for columns are of the form schemaName.tableName.columnName.

To match the name of a column, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the expression is used to match the entire name string of the column; it does not match substrings that might be present in a column name.
If you include this property in the configuration, do not set the column.include.list property.

false

Specifies whether to skip publishing messages when there is no change in included columns. This would essentially filter messages if there is no change in columns included as per column.include.list or column.exclude.list properties.

Note: Only works when REPLICA IDENTITY of the table is set to FULL

adaptive

Time, date, and timestamps can be represented with different kinds of precision:

adaptive captures the time and timestamp values exactly as in the database using either millisecond, microsecond, or nanosecond precision values based on the database column’s type.

adaptive_time_microseconds captures the date, datetime and timestamp values exactly as in the database using either millisecond, microsecond, or nanosecond precision values based on the database column’s type. An exception is TIME type fields, which are always captured as microseconds.

connect always represents time and timestamp values by using Kafka Connect’s built-in representations for Time, Date, and Timestamp, which use millisecond precision regardless of the database columns’ precision. For more information, see temporal values.

precise

Specifies how the connector should handle values for DECIMAL and NUMERIC columns:

precise represents values by using java.math.BigDecimal to represent values in binary form in change events.

double represents values by using double values, which might result in a loss of precision but which is easier to use.

string encodes values as formatted strings, which are easy to consume but semantic information about the real type is lost. For more information, see Decimal types.

map

Specifies how the connector should handle values for hstore columns:

map represents values by using MAP.

json represents values by using json string. This setting encodes values as formatted strings such as {“key” : “val”}. For more information, see PostgreSQL HSTORE type.

numeric

Specifies how the connector should handle values for interval columns:

numeric represents intervals using approximate number of microseconds.

string represents intervals exactly by using the string pattern representation P<years>Y<months>M<days>DT<hours>H<minutes>M<seconds>S. For example: P1Y2M3DT4H5M6.78S. For more information, see PostgreSQL basic types.

prefer

Whether to use an encrypted connection to the PostgreSQL server. Options include:

disable uses an unencrypted connection.

allow attempts to use an unencrypted connection first and, failing that, a secure (encrypted) connection.

prefer attempts to use a secure (encrypted) connection first and, failing that, an unencrypted connection.

require uses a secure (encrypted) connection, and fails if one cannot be established.

verify-ca behaves like require but also verifies the server TLS certificate against the configured Certificate Authority (CA) certificates, or fails if no valid matching CA certificates are found.

verify-full behaves like verify-ca but also verifies that the server certificate matches the host to which the connector is trying to connect. For more information, see the PostgreSQL documentation.

No default

The path to the file that contains the SSL certificate for the client. For more information, see the PostgreSQL documentation.

No default

The path to the file that contains the SSL private key of the client. For more information, see the PostgreSQL documentation.

No default

The password to access the client private key from the file specified by database.sslkey. For more information, see the PostgreSQL documentation.

No default

The path to the file that contains the root certificate(s) against which the server is validated. For more information, see the PostgreSQL documentation.

true

Enable TCP keep-alive probe to verify that the database connection is still alive. For more information, see the PostgreSQL documentation.

true

Controls whether a delete event is followed by a tombstone event.

true - a delete operation is represented by a delete event and a subsequent tombstone event.

false - only a delete event is emitted.

After a source record is deleted, emitting a tombstone event (the default behavior) allows Kafka to completely delete all events that pertain to the key of the deleted row in case log compaction is enabled for the topic.

n/a

An optional, comma-separated list of regular expressions that match the fully-qualified names of character-based columns. Set this property if you want to truncate the data in a set of columns when it exceeds the number of characters specified by the length in the property name. Set length to a positive integer value, for example, column.truncate.to.20.chars.

The fully-qualified name of a column observes the following format: <schemaName>.<tableName>.<columnName>. To match the name of a column, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire name string of the column; the expression does not match substrings that might be present in a column name.

You can specify multiple properties with different lengths in a single configuration.

n/a

An optional, comma-separated list of regular expressions that match the fully-qualified names of character-based columns. Set this property if you want the connector to mask the values for a set of columns, for example, if they contain sensitive data. Set length to a positive integer to replace data in the specified columns with the number of asterisk () characters specified by the length in the property name. Set length to 0 (zero) to replace data in the specified columns with an empty string.

The fully-qualified name of a column observes the following format: schemaName.tableName.columnName. To match the name of a column, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire name string of the column; the expression does not match substrings that might be present in a column name.

You can specify multiple properties with different lengths in a single configuration.

n/a

An optional, comma-separated list of regular expressions that match the fully-qualified names of character-based columns. Fully-qualified names for columns are of the form <schemaName>.<tableName>.<columnName>.
To match the name of a column Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire name string of the column; the expression does not match substrings that might be present in a column name. In the resulting change event record, the values for the specified columns are replaced with pseudonyms.

A pseudonym consists of the hashed value that results from applying the specified hashAlgorithm and salt. Based on the hash function that is used, referential integrity is maintained, while column values are replaced with pseudonyms. Supported hash functions are described in the MessageDigest section of the Java Cryptography Architecture Standard Algorithm Name Documentation.

In the following example, CzQMA0cB5K is a randomly selected salt.

  1. column.mask.hash.SHA-256.with.salt.CzQMA0cB5K = inventory.orders.customerName, inventory.shipment.customerName

If necessary, the pseudonym is automatically shortened to the length of the column. The connector configuration can include multiple properties that specify different hash algorithms and salts.

Depending on the hashAlgorithm used, the salt selected, and the actual data set, the resulting data set might not be completely masked.

Hashing strategy version 2 should be used to ensure fidelity if the value is being hashed in different places or systems.

n/a

An optional, comma-separated list of regular expressions that match the fully-qualified names of columns for which you want the connector to emit extra parameters that represent column metadata. When this property is set, the connector adds the following fields to the schema of event records:

  • debezium.source.column.type

  • debezium.source.column.length

  • debezium.source.column.scale

These parameters propagate a column’s original type name and length (for variable-width types), respectively.
Enabling the connector to emit this extra data can assist in properly sizing specific numeric or character-based columns in sink databases.

The fully-qualified name of a column observes one of the following formats: databaseName.tableName.columnName, or databaseName.schemaName.tableName.columnName.
To match the name of a column, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire name string of the column; the expression does not match substrings that might be present in a column name.

n/a

An optional, comma-separated list of regular expressions that specify the fully-qualified names of data types that are defined for columns in a database. When this property is set, for columns with matching data types, the connector emits event records that include the following extra fields in their schema:

  • debezium.source.column.type

  • debezium.source.column.length

  • debezium.source.column.scale

These parameters propagate a column’s original type name and length (for variable-width types), respectively.
Enabling the connector to emit this extra data can assist in properly sizing specific numeric or character-based columns in sink databases.

The fully-qualified name of a column observes one of the following formats: databaseName.tableName.typeName, or databaseName.schemaName.tableName.typeName.
To match the name of a data type, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire name string of the data type; the expression does not match substrings that might be present in a type name.

For the list of PostgreSQL-specific data type names, see the PostgreSQL data type mappings.

empty string

A list of expressions that specify the columns that the connector uses to form custom message keys for change event records that it publishes to the Kafka topics for specified tables.

By default, Debezium uses the primary key column of a table as the message key for records that it emits. In place of the default, or to specify a key for tables that lack a primary key, you can configure custom message keys based on one or more columns.

To establish a custom message key for a table, list the table, followed by the columns to use as the message key. Each list entry takes the following format:

<fully-qualified_tableName>:<keyColumn>,<keyColumn>

To base a table key on multiple column names, insert commas between the column names.

Each fully-qualified table name is a regular expression in the following format:

<schemaName>.<tableName>

The property can include entries for multiple tables. Use a semicolon to separate table entries in the list.

The following example sets the message key for the tables inventory.customers and purchase.orders:

inventory.customers:pk1,pk2;(.).purchaseorders:pk3,pk4

For the table inventory.customer, the columns pk1 and pk2 are specified as the message key. For the purchaseorders tables in any schema, the columns pk3 and pk4 server as the message key.

There is no limit to the number of columns that you use to create custom message keys. However, it’s best to use the minimum number that are required to specify a unique key.

Note that having this property set and REPLICA IDENTITY set to DEFAULT on the tables, will cause the tombstone events to not be created properly if the key columns are not part of the primary key of the table.
Setting REPLICA IDENTITY to FULL is the only solution.

all_tables

Applies only when streaming changes by using the pgoutput plug-in. The setting determines how creation of a publication should work. Specify one of the following values:

all_tables - If a publication exists, the connector uses it. If a publication does not exist, the connector creates a publication for all tables in the database for which the connector is capturing changes. For the connector to create a publication it must access the database through a database user account that has permission to create publications and perform replications. You grant the required permission by using the following SQL command CREATE PUBLICATION <publication_name> FOR ALL TABLES;.

disabled - The connector does not attempt to create a publication. A database administrator or the user configured to perform replications must have created the publication before running the connector. If the connector cannot find the publication, the connector throws an exception and stops.

filtered - If a publication exists, the connector uses it. If no publication exists, the connector creates a new publication for tables that match the current filter configuration as specified by the schema.include.list, schema.exclude.list, and table.include.list, and table.exclude.list connector configuration properties. For example: CREATE PUBLICATION <publication_name> FOR TABLE <tbl1, tbl2, tbl3>. If the publication exists, the connector updates the publication for tables that match the current filter configuration. For example: ALTER PUBLICATION <publication_name> SET TABLE <tbl1, tbl2, tbl3>.

empty string

The setting determines the value for replica identity at table level.

This option will overwrite the existing value in database. A comma-separated list of regular expressions that match fully-qualified tables and replica identity value to be used in the table.

Each expression must match the pattern ‘<fully-qualified table name>:<replica identity>’, where the table name could be defined as (SCHEMA_NAME.TABLE_NAME), and the replica identity values are:

DEFAULT - Records the old values of the columns of the primary key, if any. This is the default for non-system tables.

INDEX index_name - Records the old values of the columns covered by the named index, that must be unique, not partial, not deferrable, and include only columns marked NOT NULL. If this index is dropped, the behavior is the same as NOTHING.

FULL - Records the old values of all columns in the row.

NOTHING - Records no information about the old row. This is the default for system tables.

For example,

  1. schema1.*:FULL,schema2.table2:NOTHING,schema2.table3:INDEX idx_name

bytes

Specifies how binary (bytea) columns should be represented in change events:

bytes represents binary data as byte array.

base64 represents binary data as base64-encoded strings.

base64-url-safe represents binary data as base64-url-safe-encoded strings.

hex represents binary data as hex-encoded (base16) strings.

none

Specifies how schema names should be adjusted for compatibility with the message converter used by the connector. Possible settings:

  • none does not apply any adjustment.

  • avro replaces the characters that cannot be used in the Avro type name with underscore.

  • avro_unicode replaces the underscore or characters that cannot be used in the Avro type name with corresponding unicode like _uxxxx. Note: is an escape sequence like backslash in Java

none

Specifies how field names should be adjusted for compatibility with the message converter used by the connector. Possible settings:

  • none does not apply any adjustment.

  • avro replaces the characters that cannot be used in the Avro type name with underscore.

  • avrounicode replaces the underscore or characters that cannot be used in the Avro type name with corresponding unicode like _uxxxx. Note: is an escape sequence like backslash in Java

For more information, see Avro naming.

2

Specifies how many decimal digits should be used when converting Postgres money type to java.math.BigDecimal, which represents the values in change events. Applicable only when decimal.handling.mode is set to precise.

No default

An optional, comma-separated list of regular expressions that match the names of the logical decoding message prefixes that you want the connector to capture. By default, the connector captures all logical decoding messages. When this property is set, the connector captures only logical decoding message with the prefixes specified by the property. All other logical decoding messages are excluded.

To match the name of a message prefix, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire message prefix string; the expression does not match substrings that might be present in a prefix.

If you include this property in the configuration, do not also set the message.prefix.exclude.list property.

For information about the structure of message events and about their ordering semantics, see message events.

No default

An optional, comma-separated list of regular expressions that match the names of the logical decoding message prefixes that you do not want the connector to capture. When this property is set, the connector does not capture logical decoding messages that use the specified prefixes. All other messages are captured.
To exclude all logical decoding messages, set the value of this property to .*.

To match the name of a message prefix, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire message prefix string; the expression does not match substrings that might be present in a prefix.

If you include this property in the configuration, do not also set message.prefix.include.list property.

For information about the structure of message events and about their ordering semantics, see message events.

The following advanced configuration properties have defaults that work in most situations and therefore rarely need to be specified in the connector’s configuration.

Table 26. Advanced connector configuration properties
PropertyDefaultDescription

No default

Enumerates a comma-separated list of the symbolic names of the custom converter instances that the connector can use. For example,

isbn

You must set the converters property to enable the connector to use a custom converter.

For each converter that you configure for a connector, you must also add a .type property, which specifies the fully-qualifed name of the class that implements the converter interface. The .type property uses the following format:

<converterSymbolicName>.type

For example,

  1. isbn.type: io.debezium.test.IsbnConverter

If you want to further control the behavior of a configured converter, you can add one or more configuration parameters to pass values to the converter. To associate any additional configuration parameter with a converter, prefix the parameter names with the symbolic name of the converter.
For example,

  1. isbn.schema.name: io.debezium.postgresql.type.Isbn

initial

Specifies the criteria for performing a snapshot when the connector starts:

initial - The connector performs a snapshot only when no offsets have been recorded for the logical server name.

always - The connector performs a snapshot each time the connector starts.

never - The connector never performs snapshots. When a connector is configured this way, its behavior when it starts is as follows. If there is a previously stored LSN in the Kafka offsets topic, the connector continues streaming changes from that position. If no LSN has been stored, the connector starts streaming changes from the point in time when the PostgreSQL logical replication slot was created on the server. The never snapshot mode is useful only when you know all data of interest is still reflected in the WAL.

initial_only - The connector performs an initial snapshot and then stops, without processing any subsequent changes.

exported - deprecated

custom - The connector performs a snapshot according to the setting for the snapshot.custom.class property, which is a custom implementation of the io.debezium.connector.postgresql.spi.Snapshotter interface.

For more information, see the table of snapshot.mode options.

No default

A full Java class name that is an implementation of the io.debezium.connector.postgresql.spi.Snapshotter interface. Required when the snapshot.mode property is set to custom. See custom snapshotter SPI.

All tables specified in table.include.list

An optional, comma-separated list of regular expressions that match the fully-qualified names (<schemaName>.<tableName>) of the tables to include in a snapshot. The specified items must be named in the connector’s table.include.list property. This property takes effect only if the connector’s snapshot.mode property is set to a value other than never.
This property does not affect the behavior of incremental snapshots.

To match the name of a table, Debezium applies the regular expression that you specify as an anchored regular expression. That is, the specified expression is matched against the entire name string of the table; it does not match substrings that might be present in a table name.

10000

Positive integer value that specifies the maximum amount of time (in milliseconds) to wait to obtain table locks when performing a snapshot. If the connector cannot acquire table locks in this time interval, the snapshot fails. How the connector performs snapshots provides details.

No default

Specifies the table rows to include in a snapshot. Use the property if you want a snapshot to include only a subset of the rows in a table. This property affects snapshots only. It does not apply to events that the connector reads from the log.

The property contains a comma-separated list of fully-qualified table names in the form <schemaName>.<tableName>. For example,

“snapshot.select.statement.overrides”: “inventory.products,customers.orders”

For each table in the list, add a further configuration property that specifies the SELECT statement for the connector to run on the table when it takes a snapshot. The specified SELECT statement determines the subset of table rows to include in the snapshot. Use the following format to specify the name of this SELECT statement property:

snapshot.select.statement.overrides.<schemaName>.<tableName>. For example, snapshot.select.statement.overrides.customers.orders.

Example:

From a customers.orders table that includes the soft-delete column, delete_flag, add the following properties if you want a snapshot to include only those records that are not soft-deleted:

  1. snapshot.select.statement.overrides”: customer.orders”,
  2. snapshot.select.statement.overrides.customer.orders”: SELECT * FROM [customers].[orders] WHERE delete_flag = 0 ORDER BY id DESC

In the resulting snapshot, the connector includes only the records for which delete_flag = 0.

fail

Specifies how the connector should react to exceptions during processing of events:

fail propagates the exception, indicates the offset of the problematic event, and causes the connector to stop.

warn logs the offset of the problematic event, skips that event, and continues processing.

skip skips the problematic event and continues processing.

2048

Positive integer value that specifies the maximum size of each batch of events that the connector processes.

8192

Positive integer value that specifies the maximum number of records that the blocking queue can hold. When Debezium reads events streamed from the database, it places the events in the blocking queue before it writes them to Kafka. The blocking queue can provide backpressure for reading change events from the database in cases where the connector ingests messages faster than it can write them to Kafka, or when Kafka becomes unavailable. Events that are held in the queue are disregarded when the connector periodically records offsets. Always set the value of max.queue.size to be larger than the value of max.batch.size.

0

A long integer value that specifies the maximum volume of the blocking queue in bytes. By default, volume limits are not specified for the blocking queue. To specify the number of bytes that the queue can consume, set this property to a positive long value.
If max.queue.size is also set, writing to the queue is blocked when the size of the queue reaches the limit specified by either property. For example, if you set max.queue.size=1000, and max.queue.size.in.bytes=5000, writing to the queue is blocked after the queue contains 1000 records, or after the volume of the records in the queue reaches 5000 bytes.

500

Positive integer value that specifies the number of milliseconds the connector should wait for new change events to appear before it starts processing a batch of events. Defaults to 500 milliseconds.

false

Specifies connector behavior when the connector encounters a field whose data type is unknown. The default behavior is that the connector omits the field from the change event and logs a warning.

Set this property to true if you want the change event to contain an opaque binary representation of the field. This lets consumers decode the field. You can control the exact representation by setting the binary handling mode property.

Consumers risk backward compatibility issues when include.unknown.datatypes is set to true. Not only may the database-specific binary representation change between releases, but if the data type is eventually supported by Debezium, the data type will be sent downstream in a logical type, which would require adjustments by consumers. In general, when encountering unsupported data types, create a feature request so that support can be added.

No default

A semicolon separated list of SQL statements that the connector executes when it establishes a JDBC connection to the database. To use a semicolon as a character and not as a delimiter, specify two consecutive semicolons, ;;.

The connector may establish JDBC connections at its own discretion. Consequently, this property is useful for configuration of session parameters only, and not for executing DML statements.

The connector does not execute these statements when it creates a connection for reading the transaction log.

10000

Frequency for sending replication connection status updates to the server, given in milliseconds.
The property also controls how frequently the database status is checked to detect a dead connection in case the database was shut down.

0

Controls how frequently the connector sends heartbeat messages to a Kafka topic. The default behavior is that the connector does not send heartbeat messages.

Heartbeat messages are useful for monitoring whether the connector is receiving change events from the database. Heartbeat messages might help decrease the number of change events that need to be re-sent when a connector restarts. To send heartbeat messages, set this property to a positive integer, which indicates the number of milliseconds between heartbeat messages.

Heartbeat messages are needed when there are many updates in a database that is being tracked but only a tiny number of updates are related to the table(s) and schema(s) for which the connector is capturing changes. In this situation, the connector reads from the database transaction log as usual but rarely emits change records to Kafka. This means that no offset updates are committed to Kafka and the connector does not have an opportunity to send the latest retrieved LSN to the database. The database retains WAL files that contain events that have already been processed by the connector. Sending heartbeat messages enables the connector to send the latest retrieved LSN to the database, which allows the database to reclaim disk space being used by no longer needed WAL files.

No default

Specifies a query that the connector executes on the source database when the connector sends a heartbeat message.

This is useful for resolving the situation described in WAL disk space consumption, where capturing changes from a low-traffic database on the same host as a high-traffic database prevents Debezium from processing WAL records and thus acknowledging WAL positions with the database. To address this situation, create a heartbeat table in the low-traffic database, and set this property to a statement that inserts records into that table, for example:

INSERT INTO test_heartbeat_table (text) VALUES (‘test_heartbeat’)

This allows the connector to receive changes from the low-traffic database and acknowledge their LSNs, which prevents unbounded WAL growth on the database host.

columns_diff

Specify the conditions that trigger a refresh of the in-memory schema for a table.

columns_diff is the safest mode. It ensures that the in-memory schema stays in sync with the database table’s schema at all times.

columns_diff_exclude_unchanged_toast instructs the connector to refresh the in-memory schema cache if there is a discrepancy with the schema derived from the incoming message, unless unchanged TOASTable data fully accounts for the discrepancy.

This setting can significantly improve connector performance if there are frequently-updated tables that have TOASTed data that are rarely part of updates. However, it is possible for the in-memory schema to become outdated if TOASTable columns are dropped from the table.

No default

An interval in milliseconds that the connector should wait before performing a snapshot when the connector starts. If you are starting multiple connectors in a cluster, this property is useful for avoiding snapshot interruptions, which might cause re-balancing of connectors.

10240

During a snapshot, the connector reads table content in batches of rows. This property specifies the maximum number of rows in a batch.

No default

Semicolon separated list of parameters to pass to the configured logical decoding plug-in. For example, add-tables=public.table,public.table2;include-lsn=true.

6

If connecting to a replication slot fails, this is the maximum number of consecutive attempts to connect.

10000 (10 seconds)

The number of milliseconds to wait between retry attempts when the connector fails to connect to a replication slot.

debezium_unavailable_value

Specifies the constant that the connector provides to indicate that the original value is a toasted value that is not provided by the database. If the setting of unavailable.value.placeholder starts with the hex: prefix it is expected that the rest of the string represents hexadecimally encoded octets. For more information, see toasted values.

false

Determines whether the connector generates events with transaction boundaries and enriches change event envelopes with transaction metadata. Specify true if you want the connector to do this. For more information, see Transaction metadata.

true

Determines whether the connector should commit the LSN of the processed records in the source postgres database so that the WAL logs can be deleted. Specify false if you don’t want the connector to do this. Please note that if set to false LSN will not be acknowledged by Debezium and as a result WAL logs will not be cleared which might result in disk space issues. User is expected to handle the acknowledgement of LSN outside Debezium.

10000 (10 seconds)

The number of milliseconds to wait before restarting a connector after a retriable error occurs.

t

A comma-separated list of operation types that will be skipped during streaming. The operations include: c for inserts/create, u for updates, d for deletes, t for truncates, and none to not skip any operations. By default, truncate operations are skipped.

No default value

Fully-qualified name of the data collection that is used to send signals to the connector.
Use the following format to specify the collection name:
<schemaName>.<tableName>

source

List of the signaling channel names that are enabled for the connector. By default, the following channels are available:

No default

List of notification channel names that are enabled for the connector. By default, the following channels are available:

1024

The maximum number of rows that the connector fetches and reads into memory during an incremental snapshot chunk. Increasing the chunk size provides greater efficiency, because the snapshot runs fewer snapshot queries of a greater size. However, larger chunk sizes also require more memory to buffer the snapshot data. Adjust the chunk size to a value that provides the best performance in your environment.

0

How often, in milliseconds, the XMIN will be read from the replication slot. The XMIN value provides the lower bounds of where a new replication slot could start from. The default value of 0 disables tracking XMIN tracking.

io.debezium.schema.SchemaTopicNamingStrategy

The name of the TopicNamingStrategy class that should be used to determine the topic name for data change, schema change, transaction, heartbeat event etc., defaults to SchemaTopicNamingStrategy.

.

Specify the delimiter for topic name, defaults to ..

10000

The size used for holding the topic names in bounded concurrent hash map. This cache will help to determine the topic name corresponding to a given data collection.

debezium-heartbeat

Controls the name of the topic to which the connector sends heartbeat messages. The topic name has this pattern:

topic.heartbeat.prefix.topic.prefix

For example, if the topic prefix is fulfillment, the default topic name is __debezium-heartbeat.fulfillment.

transaction

Controls the name of the topic to which the connector sends transaction metadata messages. The topic name has this pattern:

topic.prefix.topic.transaction

For example, if the topic prefix is fulfillment, the default topic name is fulfillment.transaction.

1

Specifies the number of threads that the connector uses when performing an initial snapshot. To enable parallel initial snapshots, set the property to a value greater than 1. In a parallel initial snapshot, the connector processes multiple tables concurrently. This feature is incubating.

No default

The custom metric tags will accept key-value pairs to customize the MBean object name which should be appended the end of regular name, each key would represent a tag for the MBean object name, and the corresponding value would be the value of that tag the key is. For example: k1=v1,k2=v2.

-1

The maximum number of retries on retriable errors (e.g. connection errors) before failing (-1 = no limit, 0 = disabled, > 0 = num of retries).

Pass-through connector configuration properties

The connector also supports pass-through configuration properties that are used when creating the Kafka producer and consumer.

Be sure to consult the Kafka documentation for all of the configuration properties for Kafka producers and consumers. The PostgreSQL connector does use the new consumer configuration properties.

Debezium connector Kafka signals configuration properties

Debezium provides a set of signal.* properties that control how the connector interacts with the Kafka signals topic.

The following table describes the Kafka signal properties.

Table 27. Kafka signals configuration properties
PropertyDefaultDescription

<topic.prefix>-signal

The name of the Kafka topic that the connector monitors for ad hoc signals.

If automatic topic creation is disabled, you must manually create the required signaling topic. A signaling topic is required to preserve signal ordering. The signaling topic must have a single partition.

kafka-signal

The name of the group ID that is used by Kafka consumers.

No default

A list of host/port pairs that the connector uses for establishing an initial connection to the Kafka cluster. Each pair references the Kafka cluster that is used by the Debezium Kafka Connect process.

100

An integer value that specifies the maximum number of milliseconds that the connector waits when polling signals.

Debezium connector pass-through signals Kafka consumer client configuration properties

The Debezium connector provides for pass-through configuration of the signals Kafka consumer. Pass-through signals properties begin with the prefix signals.consumer.*. For example, the connector passes properties such as signal.consumer.security.protocol=SSL to the Kafka consumer.

Debezium strips the prefixes from the properties before it passes the properties to the Kafka signals consumer.

Debezium connector sink notifications configuration properties

The following table describes the notification properties.

Table 28. Sink notification configuration properties
PropertyDefaultDescription

No default

The name of the topic that receives notifications from Debezium. This property is required when you configure the notification.enabled.channels property to include sink as one of the enabled notification channels.

Monitoring

The Debezium PostgreSQL connector provides two types of metrics that are in addition to the built-in support for JMX metrics that Zookeeper, Kafka, and Kafka Connect provide.

  • Snapshot metrics provide information about connector operation while performing a snapshot.

  • Streaming metrics provide information about connector operation when the connector is capturing changes and streaming change event records.

Debezium monitoring documentation provides details for how to expose these metrics by using JMX.

Snapshot metrics

The MBean is debezium.postgres:type=connector-metrics,context=snapshot,server=_<topic.prefix>_.

Snapshot metrics are not exposed unless a snapshot operation is active, or if a snapshot has occurred since the last connector start.

The following table lists the shapshot metrics that are available.

AttributesTypeDescription

string

The last snapshot event that the connector has read.

long

The number of milliseconds since the connector has read and processed the most recent event.

long

The total number of events that this connector has seen since last started or reset.

long

The number of events that have been filtered by include/exclude list filtering rules configured on the connector.

string[]

The list of tables that are captured by the connector.

int

The length the queue used to pass events between the snapshotter and the main Kafka Connect loop.

int

The free capacity of the queue used to pass events between the snapshotter and the main Kafka Connect loop.

int

The total number of tables that are being included in the snapshot.

int

The number of tables that the snapshot has yet to copy.

boolean

Whether the snapshot was started.

boolean

Whether the snapshot was paused.

boolean

Whether the snapshot was aborted.

boolean

Whether the snapshot completed.

long

The total number of seconds that the snapshot has taken so far, even if not complete. Includes also time when snapshot was paused.

long

The total number of seconds that the snapshot was paused. If the snapshot was paused several times, the paused time adds up.

Map<String, Long>

Map containing the number of rows scanned for each table in the snapshot. Tables are incrementally added to the Map during processing. Updates every 10,000 rows scanned and upon completing a table.

long

The maximum buffer of the queue in bytes. This metric is available if max.queue.size.in.bytes is set to a positive long value.

long

The current volume, in bytes, of records in the queue.

The connector also provides the following additional snapshot metrics when an incremental snapshot is executed:

AttributesTypeDescription

string

The identifier of the current snapshot chunk.

string

The lower bound of the primary key set defining the current chunk.

string

The upper bound of the primary key set defining the current chunk.

string

The lower bound of the primary key set of the currently snapshotted table.

string

The upper bound of the primary key set of the currently snapshotted table.

Streaming metrics

The MBean is debezium.postgres:type=connector-metrics,context=streaming,server=_<topic.prefix>_.

The following table lists the streaming metrics that are available.

AttributesTypeDescription

string

The last streaming event that the connector has read.

long

The number of milliseconds since the connector has read and processed the most recent event.

long

The total number of events that this connector has seen since the last start or metrics reset.

long

The total number of create events that this connector has seen since the last start or metrics reset.

long

The total number of update events that this connector has seen since the last start or metrics reset.

long

The total number of delete events that this connector has seen since the last start or metrics reset.

long

The number of events that have been filtered by include/exclude list filtering rules configured on the connector.

string[]

The list of tables that are captured by the connector.

int

The length the queue used to pass events between the streamer and the main Kafka Connect loop.

int

The free capacity of the queue used to pass events between the streamer and the main Kafka Connect loop.

boolean

Flag that denotes whether the connector is currently connected to the database server.

long

The number of milliseconds between the last change event’s timestamp and the connector processing it. The values will incoporate any differences between the clocks on the machines where the database server and the connector are running.

long

The number of processed transactions that were committed.

Map<String, String>

The coordinates of the last received event.

string

Transaction identifier of the last processed transaction.

long

The maximum buffer of the queue in bytes. This metric is available if max.queue.size.in.bytes is set to a positive long value.

long

The current volume, in bytes, of records in the queue.

Behavior when things go wrong

Debezium is a distributed system that captures all changes in multiple upstream databases; it never misses or loses an event. When the system is operating normally or being managed carefully then Debezium provides exactly once delivery of every change event record.

If a fault does happen then the system does not lose any events. However, while it is recovering from the fault, it might repeat some change events. In these abnormal situations, Debezium, like Kafka, provides at least once delivery of change events.

The rest of this section describes how Debezium handles various kinds of faults and problems.

Configuration and startup errors

In the following situations, the connector fails when trying to start, reports an error/exception in the log, and stops running:

  • The connector’s configuration is invalid.

  • The connector cannot successfully connect to PostgreSQL by using the specified connection parameters.

  • The connector is restarting from a previously-recorded position in the PostgreSQL WAL (by using the LSN) and PostgreSQL no longer has that history available.

In these cases, the error message has details about the problem and possibly a suggested workaround. After you correct the configuration or address the PostgreSQL problem, restart the connector.

PostgreSQL becomes unavailable

When the connector is running, the PostgreSQL server that it is connected to could become unavailable for any number of reasons. If this happens, the connector fails with an error and stops. When the server is available again, restart the connector.

The PostgreSQL connector externally stores the last processed offset in the form of a PostgreSQL LSN. After a connector restarts and connects to a server instance, the connector communicates with the server to continue streaming from that particular offset. This offset is available as long as the Debezium replication slot remains intact. Never drop a replication slot on the primary server or you will lose data. For information about failure cases in which a slot has been removed, see the next section.

Cluster failures

As of release 12, PostgreSQL allows logical replication slots only on primary servers. This means that you can point a Debezium PostgreSQL connector to only the active primary server of a database cluster. Also, replication slots themselves are not propagated to replicas. If the primary server goes down, a new primary must be promoted.

Some managed PostgresSQL services (AWS RDS and GCP CloudSQL for example) implement replication to a standby via disk replication. This means that the replication slot does get replicated and will remain available after a failover.

The new primary must have the logical decoding plug-in installed and a replication slot that is configured for use by the plug-in and the database for which you want to capture changes. Only then can you point the connector to the new server and restart the connector.

There are important caveats when failovers occur and you should pause Debezium until you can verify that you have an intact replication slot that has not lost data. After a failover:

  • There must be a process that re-creates the Debezium replication slot before allowing the application to write to the new primary. This is crucial. Without this process, your application can miss change events.

  • You might need to verify that Debezium was able to read all changes in the slot before the old primary failed.

One reliable method of recovering and verifying whether any changes were lost is to recover a backup of the failed primary to the point immediately before it failed. While this can be administratively difficult, it allows you to inspect the replication slot for any unconsumed changes.

There are discussions in the PostgreSQL community around a feature called failover slots that would help mitigate this problem, but as of PostgreSQL 12, they have not been implemented. However, there is active development for PostgreSQL 13 to support logical decoding on standbys, which is a major requirement to make failover possible. You can find more about this in this community thread.

More about the concept of failover slots is in this blog post.

Kafka Connect process stops gracefully

Suppose that Kafka Connect is being run in distributed mode and a Kafka Connect process is stopped gracefully. Prior to shutting down that process, Kafka Connect migrates the process’s connector tasks to another Kafka Connect process in that group. The new connector tasks start processing exactly where the prior tasks stopped. There is a short delay in processing while the connector tasks are stopped gracefully and restarted on the new processes.

Kafka Connect process crashes

If the Kafka Connector process stops unexpectedly, any connector tasks it was running terminate without recording their most recently processed offsets. When Kafka Connect is being run in distributed mode, Kafka Connect restarts those connector tasks on other processes. However, PostgreSQL connectors resume from the last offset that was recorded by the earlier processes. This means that the new replacement tasks might generate some of the same change events that were processed just prior to the crash. The number of duplicate events depends on the offset flush period and the volume of data changes just before the crash.

Because there is a chance that some events might be duplicated during a recovery from failure, consumers should always anticipate some duplicate events. Debezium changes are idempotent, so a sequence of events always results in the same state.

In each change event record, Debezium connectors insert source-specific information about the origin of the event, including the PostgreSQL server’s time of the event, the ID of the server transaction, and the position in the write-ahead log where the transaction changes were written. Consumers can keep track of this information, especially the LSN, to determine whether an event is a duplicate.

Kafka becomes unavailable

As the connector generates change events, the Kafka Connect framework records those events in Kafka by using the Kafka producer API. Periodically, at a frequency that you specify in the Kafka Connect configuration, Kafka Connect records the latest offset that appears in those change events. If the Kafka brokers become unavailable, the Kafka Connect process that is running the connectors repeatedly tries to reconnect to the Kafka brokers. In other words, the connector tasks pause until a connection can be re-established, at which point the connectors resume exactly where they left off.

Connector is stopped for a duration

If the connector is gracefully stopped, the database can continue to be used. Any changes are recorded in the PostgreSQL WAL. When the connector restarts, it resumes streaming changes where it left off. That is, it generates change event records for all database changes that were made while the connector was stopped.

A properly configured Kafka cluster is able to handle massive throughput. Kafka Connect is written according to Kafka best practices, and given enough resources a Kafka Connect connector can also handle very large numbers of database change events. Because of this, after being stopped for a while, when a Debezium connector restarts, it is very likely to catch up with the database changes that were made while it was stopped. How quickly this happens depends on the capabilities and performance of Kafka and the volume of changes being made to the data in PostgreSQL.