Debezium Connector for SQL Server

Overview

The functionality of the connector is based upon change data capture feature provided by SQL Server Standard (since SQL Server 2016 SP1) or Enterprise edition. Using this mechanism a SQL Server capture process monitors all databases and tables the user is interested in and stores the changes into specifically created CDC tables that have stored procedure facade. The connector has been tested with SQL Server 2017, but community members have reportedly used it successfully with earlier versions up to 2014, too (as long as the CDC feature is provided).

The database operator must enable CDC for the table(s) that should be captured by the connector. The connector then produces a change event for every row-level insert, update, and delete operation that was published via the CDC API, recording all the change events for each table in a separate Kafka topic. The client applications read the Kafka topics that correspond to the database tables they’re interested in following, and react to every row-level event it sees in those topics.

The database operator normally enables CDC in the mid-life of a database an/or table. This means that the connector won’t have the complete history of all changes that have been made to the database. Therefore, when the SQL Server connector first connects to a particular SQL Server 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, we start with a consistent view of all of the data, yet continue reading without having lost any of the changes made while the snapshot was taking place.

The connector is also tolerant of failures. As the connector reads changes and produces events, it records the position in the database log (LSN / Log Sequence Number), that is associated with CDC record, with each event. If the connector stops for any reason (including communication failures, network problems, or crashes), upon restart it simply continues reading the CDC tables where it last left off. This includes snapshots: if the snapshot was not completed when the connector is stopped, upon restart it begins a new snapshot.

Setting up SQL Server

Before using the SQL Server connector to monitor the changes committed on SQL Server, first enable CDC on a monitored database. Please bear in mind that CDC cannot be enabled for master database.

  1. -- ====
  2. -- Enable Database for CDC template
  3. -- ====
  4. USE MyDB
  5. GO
  6. EXEC sys.sp_cdc_enable_db
  7. GO

Then enable CDC for each table that you plan to monitor

  1. -- =========
  2. -- Enable a Table Specifying Filegroup Option Template
  3. -- =========
  4. USE MyDB
  5. GO
  6. EXEC sys.sp_cdc_enable_table
  7. @source_schema = N'dbo',
  8. @source_name = N'MyTable',
  9. @role_name = N'MyRole',
  10. @filegroup_name = N'MyDB_CT',
  11. @supports_net_changes = 0
  12. GO

Verify that the user have access to the CDC table.

  1. -- =========
  2. -- Verify the user of the connector have access, this query should not have empty result
  3. -- =========
  4. EXEC sys.sp_cdc_help_change_data_capture
  5. GO

If the result is empty then please make sure that the user has privileges to access both the capture instance and CDC tables.

SQL Server on Azure

The SQL Server plug-in has not been tested with SQL Server on Azure. We welcome any feedback from a user to try the plug-in with database in managed environment.

SQL Server Always On

The SQL Server plug-in can capture changes from an Always On read-only replica. Few pre-requisities are necessary to be fulfilled

  • Change data capture is configured and enabled on the master node. SQL Server does not support CDC directly on replicas.

  • The configuration option database.applicationIntent must be set to ReadOnly. This is required by SQL Server. When Debezium detects this configuration option then it will:

    • set snapshot.isolation.mode to snapshot as this is the only one transaction isolation mode supported by raed-only replicas

    • commit the (read-only) transaction in every execution of the streaming query loop, as this is necessary to get the latest view on CDC data

How the SQL Server connector works

Snapshots

SQL Server CDC is not designed to store the complete history of database changes. It is thus necessary that Debezium establishes the baseline of current database content and streams it to the Kafka. This is achieved via a process called snapshotting.

By default (snapshotting mode initial) the connector will upon the first startup perform an initial consistent snapshot of the database (meaning the structure and data within any tables to be captured as per the connector’s filter configuration).

Each snapshot consists of the following steps:

  1. Determine the tables to be captured

  2. Obtain a lock on each of the monitored tables to ensure that no structural changes can occur to any of the tables. The level of the lock is determined by snapshot.isolation.mode configuration option.

  3. Read the maximum LSN (“log sequence number”) position in the server’s transaction log.

  4. Capture the structure of all relevant tables.

  5. Optionally release the locks obtained in step 2, i.e. the locks are held usually only for a short period of time.

  6. Scan all of the relevant database tables and schemas as valid at the LSN position read in step 3, and generate a READ event for each row and write that event to the appropriate table-specific Kafka topic.

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

Reading the change data tables

Upon first start-up, the connector takes a structural snapshot of the structure of the captured tables and persists this information in its internal database history topic. Then the connector identifies a change table for each of the source tables and executes the main loop

  1. For each change table read all changes that were created between last stored maximum LSN and current maximum LSN

  2. Order the read changes incrementally according to commit LSN and change LSN. This ensures that the changes are replayed by Debezium in the same order as were made to the database.

  3. Pass commit and change LSNs as offsets to Kafka Connect.

  4. Store the maximum LSN and repeat the loop.

After a restart, the connector will resume from the offset (commit and change LSNs) where it left off before.

The connector is able to detect whether the CDC is enabled or disabled for whitelisted source table during the runtime and modify its behaviour.

Topic names

The SQL Server connector writes events for all insert, update, and delete operations on a single table to a single Kafka topic. The name of the Kafka topics always takes the form serverName.schemaName.tableName, where serverName is the logical name of the connector as specified with the database.server.name configuration property, schemaName is the name of the schema where the operation occurred, and tableName is the name of the database table on which the operation occurred.

For example, consider a SQL Server installation with an inventory database that contains four tables: products, products_on_hand, customers, and orders in schema dbo. If the connector monitoring this database were given a logical server name of fulfillment, then the connector would produce events on these four Kafka topics:

  • fulfillment.dbo.products

  • fulfillment.dbo.products_on_hand

  • fulfillment.dbo.customers

  • fulfillment.dbo.orders

Schema change topic

The user-facing schema change topic is not implemented yet (see DBZ-1904).

Events

All data change events produced by the SQL Server connector have a key and a value, although the structure of the key and value depend on the table from which the change events originated (see Topic names).

The SQL Server connector ensures that all Kafka Connect schema names are valid Avro schema names. This means that the logical server name must start with Latin letters or an underscore (e.g., [a-z,A-Z,]), and the remaining characters in the logical server name and all characters in the schema and table names must be Latin letters, digits, or an underscore (e.g., [a-z,A-Z,0-9,\]). If not, then all invalid characters will automatically be replaced with an underscore character.

This can lead to unexpected conflicts when the logical server name, schema names, and table names contain other characters, and the only distinguishing characters between table full names are invalid and thus replaced with underscores.

Debezium and Kafka Connect are designed around continuous streams of event messages, and the structure of these events may change over time. This could be difficult for consumers to deal with, so to make it easy Kafka Connect makes each event self-contained. Every message key and value has two parts: a schema and payload. The schema describes the structure of the payload, while the payload contains the actual data.

Change Event Keys

For a given table, the change event’s key will have a structure that contains a field for each column in the primary key (or unique key constraint) of the table at the time the event was created.

Consider a customers table defined in the inventory database’s schema dbo:

  1. CREATE TABLE customers (
  2. id INTEGER IDENTITY(1001,1) NOT NULL PRIMARY KEY,
  3. first_name VARCHAR(255) NOT NULL,
  4. last_name VARCHAR(255) NOT NULL,
  5. email VARCHAR(255) NOT NULL UNIQUE
  6. );

If the database.server.name configuration property has the value server1, every change event for the customers table while it has this definition will feature the same key structure, which in JSON looks like this:

  1. {
  2. "schema": {
  3. "type": "struct",
  4. "fields": [
  5. {
  6. "type": "int32",
  7. "optional": false,
  8. "field": "id"
  9. }
  10. ],
  11. "optional": false,
  12. "name": "server1.dbo.customers.Key"
  13. },
  14. "payload": {
  15. "id": 1004
  16. }
  17. }

The schema portion of the key contains a Kafka Connect schema describing what is in the key portion, and in our case that means that the payload value is not optional, is a structure defined by a schema named server1.dbo.customers.Key, and has one required field named id of type int32. If we look at the value of the key’s payload field, we’ll see that it is indeed a structure (which in JSON is just an object) with a single id field, whose value is 1004.

Therefore, we interpret this key as describing the row in the dbo.customers table (output from the connector named server1) whose id primary key column had a value of 1004.

Although the column.blacklist configuration property allows you to remove columns from the event values, 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 will be null. This makes sense since the rows in a table without a primary or unique key constraint cannot be uniquely identified.

Change Event Values

Like the message key, the value of a change event message has a schema section and payload section. The payload section of every change event value produced by the SQL Server connector has an envelope structure with the following fields:

  • op is a mandatory field that contains a string value describing the type of operation. Values for the SQL Server connector are c for create (or insert), u for update, d for delete, and r for read (in the case of a snapshot).

  • before is an optional field that if present contains the state of the row before the event occurred. The structure is described by the server1.dbo.customers.Value Kafka Connect schema, which the server1 connector uses for all rows in the dbo.customers table.

  • after is an optional field that if present contains the state of the row after the event occurred. The structure is described by the same server1.dbo.customers.Value Kafka Connect schema used in before.

  • source is a mandatory field that contains a structure describing the source metadata for the event, which in the case of SQL Server contains these fields: the Debezium version, the connector name, whether the event is part of an ongoing snapshot or not, the commit LSN (not while snapshotting), the LSN of the change, database, schema and table where the change happened, and a timestamp representing the point in time when the record was changed in the source database (during snapshotting, it’ll be the point in time of snapshotting).

    Also a field event_serial_no is present during streaming. This is used to differentiate among events that have the same commit and change LSN. There are mostly two situations when you can see it present with value different from 1:

    • update events will have the value set to 2, this is because the update generates two events in the CDC change table of SQL Server (source documentation). The first one contains the old values and the second one contains new values. So the first one is dropped and the values from it are used with the second one to create the Debezium change event.

    • when a primary key is updated, then SQL Server emits two records - delete to remove the record with the old primary key value and insert to create the record with the new primary key. Both operations share the same commit and change LSN and their event numbers are 1 and 2.

  • ts_ms is optional and if present contains the time (using the system clock in the JVM running the Kafka Connect task) at which the connector processed the event.

And of course, the schema portion of the event message’s value contains a schema that describes this envelope structure and the nested fields within it.

Create events

Let’s look at what a create event value might look like for our customers table:

  1. {
  2. "schema": {
  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": "server1.dbo.customers.Value",
  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": "server1.dbo.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": "string",
  107. "optional": true,
  108. "field": "change_lsn"
  109. },
  110. {
  111. "type": "string",
  112. "optional": true,
  113. "field": "commit_lsn"
  114. },
  115. {
  116. "type": "int64",
  117. "optional": true,
  118. "field": "event_serial_no"
  119. }
  120. ],
  121. "optional": false,
  122. "name": "io.debezium.connector.sqlserver.Source",
  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": "server1.dbo.customers.Envelope"
  138. },
  139. "payload": {
  140. "before": null,
  141. "after": {
  142. "id": 1005,
  143. "first_name": "john",
  144. "last_name": "doe",
  145. "email": "john.doe@example.org"
  146. },
  147. "source": {
  148. "version": "1.0.3.Final",
  149. "connector": "sqlserver",
  150. "name": "server1",
  151. "ts_ms": 1559729468470,
  152. "snapshot": false,
  153. "db": "testDB",
  154. "schema": "dbo",
  155. "table": "customers",
  156. "change_lsn": "00000027:00000758:0003",
  157. "commit_lsn": "00000027:00000758:0005",
  158. "event_serial_no": "1"
  159. },
  160. "op": "c",
  161. "ts_ms": 1559729471739
  162. }
  163. }

If we look at the schema portion of this event’s value, we can see the schema for the envelope, the schema for the source structure (which is specific to the SQL Server connector and reused across all events), and the table-specific schemas for the before and after fields.

The names of the schemas for the before and after fields are of the form logicalName.schemaName.tableName.Value, and thus are entirely independent from all other schemas for all other tables. This means that when using the Avro Converter, the resulting Avro schemas for each table in each logical source have their own evolution and history.

If we look at the payload portion of this event’s value, we can see the information in the event, namely that it is describing that the row was created (since op=c), and that the after field value contains the values of the new inserted row’s’ id, first_name, last_name, and email columns.

It may appear that the JSON representations of the events are much larger than the rows they describe. This is true, because the JSON representation must include the schema and the payload portions of the message. It is possible and even recommended to use the to dramatically decrease the size of the actual messages written to the Kafka topics.

Update events

The value of an update change event on this table will actually have the exact same schema, and its payload is structured the same but will hold different values. Here’s an example:

  1. {
  2. "schema": { ... },
  3. "payload": {
  4. "before": {
  5. "id": 1005,
  6. "first_name": "john",
  7. "last_name": "doe",
  8. "email": "john.doe@example.org"
  9. },
  10. "after": {
  11. "id": 1005,
  12. "first_name": "john",
  13. "last_name": "doe",
  14. "email": "noreply@example.org"
  15. },
  16. "source": {
  17. "version": "1.0.3.Final",
  18. "connector": "sqlserver",
  19. "name": "server1",
  20. "ts_ms": 1559729995937,
  21. "snapshot": false,
  22. "db": "testDB",
  23. "schema": "dbo",
  24. "table": "customers",
  25. "change_lsn": "00000027:00000ac0:0002",
  26. "commit_lsn": "00000027:00000ac0:0007",
  27. "event_serial_no": "2"
  28. },
  29. "op": "u",
  30. "ts_ms": 1559729998706
  31. }
  32. }

When we compare this to the value in the insert event, we see a couple of differences in the payload section:

  • The op field value is now u, signifying that this row changed because of an update

  • The before field now has the state of the row with the values before the database commit

  • The after field now has the updated state of the row, and here was can see that the email value is now noreply@example.org.

  • The source field structure has the same fields as before, but the values are different since this event is from a different position in the transaction log.

  • The event_serial_no field has value 2. That is due to the update event composed of two events behind the scenes and we are exposing only the second one. If you are interested in details please check the source documentation and refer to the field $operation.

  • The ts_ms shows the timestamp that Debezium processed this event.

There are several things we can learn by just looking at this payload section. We can compare the before and after structures to determine what actually changed in this row because of the commit. The source structure tells us information about SQL Server’s record of this change (providing traceability), but more importantly this has information we can compare to other events in this and other topics to know whether this event occurred before, after, or as part of the same SQL Server commit as other events.

When the columns for a row’s primary/unique key are updated, the value of the row’s key has changed so Debezium will output three events: a DELETE event and a tombstone event with the old key for the row, followed by an INSERT event with the new key for the row.

Delete events

So far we’ve seen samples of create and update events. Now, let’s look at the value of a delete event for the same table. Once again, the schema portion of the value is exactly the same as with the create and update events:

  1. {
  2. "schema": { ... },
  3. },
  4. "payload": {
  5. "before": {
  6. "id": 1005,
  7. "first_name": "john",
  8. "last_name": "doe",
  9. "email": "noreply@example.org"
  10. },
  11. "after": null,
  12. "source": {
  13. "version": "1.0.3.Final",
  14. "connector": "sqlserver",
  15. "name": "server1",
  16. "ts_ms": 1559730445243,
  17. "snapshot": false,
  18. "db": "testDB",
  19. "schema": "dbo",
  20. "table": "customers",
  21. "change_lsn": "00000027:00000db0:0005",
  22. "commit_lsn": "00000027:00000db0:0007",
  23. "event_serial_no": "1"
  24. },
  25. "op": "d",
  26. "ts_ms": 1559730450205
  27. }
  28. }

If we look at the payload portion, we see a number of differences compared with the create or update event payloads:

  • The op field value is now d, signifying that this row was deleted

  • The before field now has the state of the row that was deleted with the database commit.

  • The after field is null, signifying that the row no longer exists

  • The source field structure has many of the same values as before, except the ts_ms, commit_lsn and change_lsn fields have changed

  • The ts_ms shows the timestamp that Debezium processed this event.

This event gives a consumer all kinds of information that it can use to process the removal of this row.

The SQL Server connector’s events are designed to work with Kafka log compaction, which allows for the removal of some older messages as long as at least the most recent message for every key is kept. This allows Kafka to reclaim storage space while ensuring the topic contains a complete dataset and can be used for reloading key-based state.

When a row is deleted, the delete event value listed above still works with log compaction, since Kafka can still remove all earlier messages with that same key. But only if the message value is null will Kafka know that it can remove all messages with that same key. To make this possible, the SQL Server connector always follows the delete event with a special tombstone event that has the same key but null value.

Database schema evolution

Debezium is able to capture schema changes over time. Due to the way CDC is implemented in SQL Server, it is necessary to work in co-operation with a database operator in order to ensure the connector continues to produce data change events when the schema is updated.

As was already mentioned before, Debezium uses SQL Server’s change data capture functionality. This means that SQL Server creates a capture table that contains all changes executed on the source table. Unfortunately, the capture table is static and needs to be updated when the source table structure changes. This update is not done by the connector itself but must be executed by an operator with elevated privileges.

There are generally two procedures how to execute the schema change:

  • cold - this is executed when Debezium is stopped

  • hot - executed while Debezium is running

Both approaches have their own advantages and disadvantages.

In both cases, it is critically important to execute the procedure completely before a new schema update on the same source table is made. It is thus recommended to execute all DDLs in a single batch so the procedure is done only once.

Not all schema changes are supported when CDC is enabled for a source table. One such exception identified is renaming a column or changing its type, SQL Server will not allow executing the operation.

Although not required by SQL Server’s CDC mechanism itself, a new capture instance must be created when altering a column from NULL to NOT NULL or vice versa. This is required so that the SQL Server connector can pick up that changed information. Otherwise, emitted change events will have the optional value for the corresponding field (true or false) set to match the original value.

Cold schema update

This is the safest procedure but might not be feasible for applications with high-availability requirements. The operator should follow this sequence of steps

  1. Suspend the application that generates the database records

  2. Wait for Debezium to stream all unstreamed changes

  3. Stop the connector

  4. Apply all changes to the source table schema

  5. Create a new capture table for the update source table using sys.sp_cdc_enable_table procedure with a unique value for parameter @capture_instance

  6. Resume the application

  7. Start the connector

  8. When Debezium starts streaming from the new capture table it is possible to drop the old one using sys.sp_cdc_disable_table stored procedure with parameter @capture_instance set to the old capture instance name

Hot schema update

The hot schema update does not require any downtime in application and data processing. The procedure itself is also much simpler than in case of cold schema update

  1. Apply all changes to the source table schema

  2. Create a new capture table for the update source table using sys.sp_cdc_enable_table procedure with a unique value for parameter @capture_instance

  3. When Debezium starts streaming from the new capture table it is possible to drop the old one using sys.sp_cdc_disable_table stored procedure with parameter @capture_instance set to the old capture instance name

The hot schema update has one drawback. There is a period of time between the database schema update and creating the new capture instance. All changes that will arrive during this period are captured by the old instance with the old structure. For instance this means that in case of a newly added column any change event produced during this time will not yet contain a field for that new column. If your application does not tolerate such a transition period we recommend to follow the cold schema update.

Example

Let’s deploy the SQL Server based Debezium tutorial to demonstrate the hot schema update.

In this example, a column phone_number is added to the customers table.

  1. # Start the database shell
  2. docker-compose -f docker-compose-sqlserver.yaml exec sqlserver bash -c '/opt/mssql-tools/bin/sqlcmd -U sa -P $SA_PASSWORD -d testDB'
  1. -- Modify the source table schema
  2. ALTER TABLE customers ADD phone_number VARCHAR(32);
  3. -- Create the new capture instance
  4. EXEC sys.sp_cdc_enable_table @source_schema = 'dbo', @source_name = 'customers', @role_name = NULL, @supports_net_changes = 0, @capture_instance = 'dbo_customers_v2';
  5. GO
  6. -- Insert new data
  7. INSERT INTO customers(first_name,last_name,email,phone_number) VALUES ('John','Doe','john.doe@example.com', '+1-555-123456');
  8. GO

Kafka Connect log will contain messages like these:

  1. connect_1 | 2019-01-17 10:11:14,924 INFO || Multiple capture instances present for the same table: Capture instance "dbo_customers" [sourceTableId=testDB.dbo.customers, changeTableId=testDB.cdc.dbo_customers_CT, startLsn=00000024:00000d98:0036, changeTableObjectId=1525580473, stopLsn=00000025:00000ef8:0048] and Capture instance "dbo_customers_v2" [sourceTableId=testDB.dbo.customers, changeTableId=testDB.cdc.dbo_customers_v2_CT, startLsn=00000025:00000ef8:0048, changeTableObjectId=1749581271, stopLsn=NULL] [io.debezium.connector.sqlserver.SqlServerStreamingChangeEventSource]
  2. connect_1 | 2019-01-17 10:11:14,924 INFO || Schema will be changed for ChangeTable [captureInstance=dbo_customers_v2, sourceTableId=testDB.dbo.customers, changeTableId=testDB.cdc.dbo_customers_v2_CT, startLsn=00000025:00000ef8:0048, changeTableObjectId=1749581271, stopLsn=NULL] [io.debezium.connector.sqlserver.SqlServerStreamingChangeEventSource]
  3. ...
  4. connect_1 | 2019-01-17 10:11:33,719 INFO || Migrating schema to ChangeTable [captureInstance=dbo_customers_v2, sourceTableId=testDB.dbo.customers, changeTableId=testDB.cdc.dbo_customers_v2_CT, startLsn=00000025:00000ef8:0048, changeTableObjectId=1749581271, stopLsn=NULL] [io.debezium.connector.sqlserver.SqlServerStreamingChangeEventSource]

Eventually, there is a new field in the schema and value of the messages written to the Kafka topic.

  1. ...
  2. {
  3. "type": "string",
  4. "optional": true,
  5. "field": "phone_number"
  6. }
  7. ...
  8. "after": {
  9. "id": 1005,
  10. "first_name": "John",
  11. "last_name": "Doe",
  12. "email": "john.doe@example.com",
  13. "phone_number": "+1-555-123456"
  14. },
  1. -- Drop the old capture instance
  2. EXEC sys.sp_cdc_disable_table @source_schema = 'dbo', @source_name = 'dbo_customers', @capture_instance = 'dbo_customers';
  3. GO

Data types

As described above, the SQL Server connector represents the changes to rows with events that are structured like the table in which the row exist. The event contains a field for each column value, and how that value is represented in the event depends on the SQL data type of the column. This section describes this mapping.

The following table describes how the connector maps each of the SQL Server data types to a literal type and semantic type within the events’ fields. Here, the literal type describes how the value is literally represented using Kafka Connect schema types, namely INT8, INT16, INT32, INT64, FLOAT32, FLOAT64, BOOLEAN, STRING, BYTES, ARRAY, MAP, and STRUCT. The 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.

SQL Server Data TypeLiteral type (schema type)Semantic type (schema name)Notes

BIT

BOOLEAN

n/a

TINYINT

INT16

n/a

SMALLINT

INT16

n/a

INT

INT32

n/a

BIGINT

INT64

n/a

REAL

FLOAT32

n/a

FLOAT[(N)]

FLOAT64

n/a

CHAR[(N)]

STRING

n/a

VARCHAR[(N)]

STRING

n/a

TEXT

STRING

n/a

NCHAR[(N)]

STRING

n/a

NVARCHAR[(N)]

STRING

n/a

NTEXT

STRING

n/a

XML

STRING

io.debezium.data.Xml

Contains the string representation of a XML document

DATETIMEOFFSET[(P)]

STRING

io.debezium.time.ZonedTimestamp

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

Other data type mappings are described in the following sections.

If present, a column’s default value is propagated to the corresponding field’s Kafka Connect schema. Change messages will contain the field’s default value (unless an explicit column value had been given), so there should rarely be the need to obtain the default value from the schema. Passing the default value helps though with satisfying the compatibility rules when using Avro as serialization format together with the Confluent schema registry.

Temporal values

Other than SQL Server’s DATETIMEOFFSET data type (which contain time zone information), the other temporal types depend on the value of the time.precision.mode configuration property. When the time.precision.mode configuration property is set to adaptive (the default), then the connector will determine the literal type and semantic type for the temporal types based on the column’s data type definition so that events exactly represent the values in the database:

SQL Server Data TypeLiteral type (schema type)Semantic type (schema name)Notes

DATE

INT32

io.debezium.time.Date

Represents the number of days since epoch.

TIME(0), 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.

TIME(7)

INT64

io.debezium.time.NanoTime

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

DATETIME

INT64

io.debezium.time.Timestamp

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

SMALLDATETIME

INT64

io.debezium.time.Timestamp

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

DATETIME2(0), DATETIME2(1), DATETIME2(2), DATETIME2(3)

INT64

io.debezium.time.Timestamp

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

DATETIME2(4), DATETIME2(5), DATETIME2(6)

INT64

io.debezium.time.MicroTimestamp

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

DATETIME2(7)

INT64

io.debezium.time.NanoTimestamp

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

When the time.precision.mode configuration property is set to connect, then the connector will use the predefined Kafka Connect logical types. This may be useful when consumers only know about the built-in Kafka Connect logical types and are unable to handle variable-precision time values. On the other hand, since SQL Server supports tenth of microsecond precision, the events generated by a connector with the connect time precision mode will result in a loss of precision when the database column has a fractional second precision value greater than 3:

SQL Server Data TypeLiteral type (schema type)Semantic type (schema name)Notes

DATE

INT32

org.apache.kafka.connect.data.Date

Represents the number of days since epoch.

TIME([P])

INT64

org.apache.kafka.connect.data.Time

Represents the number of milliseconds since midnight, and does not include timezone information. SQL Server allows P to be in the range 0-7 to store up to tenth of microsecond precision, though this mode results in a loss of precision when P > 3.

DATETIME

INT64

org.apache.kafka.connect.data.Timestamp

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

SMALLDATETIME

INT64

org.apache.kafka.connect.data.Timestamp

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

DATETIME2

INT64

org.apache.kafka.connect.data.Timestamp

Represents the number of milliseconds since epoch, and does not include timezone information. SQL Server allows P to be in the range 0-7 to store up to tenth of microsecond precision, though this mode results in a loss of precision when P > 3.

Timestamp values

The DATETIME, SMALLDATETIME and DATETIME2 types represent a timestamp without time zone information. Such columns are converted into an equivalent Kafka Connect value based on UTC. So for instance the DATETIME2 value “2018-06-20 15:13:16.945104” is represented by a io.debezium.time.MicroTimestamp with the value “1529507596945104”.

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

Decimal values

SQL Server Data TypeLiteral type (schema type)Semantic type (schema name)Notes

NUMERIC[(P[,S])]

BYTES

org.apache.kafka.connect.data.Decimal

The scale schema parameter contains an integer representing how many digits the decimal point was shifted. The connect.decimal.precision schema parameter contains an integer representing the precision of the given decimal value.

DECIMAL[(P[,S])]

BYTES

org.apache.kafka.connect.data.Decimal

The scale schema parameter contains an integer representing how many digits the decimal point was shifted. The connect.decimal.precision schema parameter contains an integer representing the precision of the given decimal value.

SMALLMONEY

BYTES

org.apache.kafka.connect.data.Decimal

The scale schema parameter contains an integer representing how many digits the decimal point was shifted. The connect.decimal.precision schema parameter contains an integer representing the precision of the given decimal value.

MONEY

BYTES

org.apache.kafka.connect.data.Decimal

The scale schema parameter contains an integer representing how many digits the decimal point was shifted. The connect.decimal.precision schema parameter contains an integer representing the precision of the given decimal value.

Deploying the SQL Server connector

If you’ve already installed Zookeeper, Kafka, and Kafka Connect, then using Debezium’s SQL Server` connector is easy. Simply download the connector’s plugin archive, extract the JARs into your Kafka Connect environment, and add the directory with the JARs to Kafka Connect’s plugin.path. Restart your Kafka Connect process to pick up the new JARs.

If immutable containers are your thing, then check out Debezium’s Docker images for Zookeeper, Kafka and Kafka Connect with the SQL Server connector already pre-installed and ready to go. You can even run Debezium on OpenShift.

Example configuration

To use the connector to produce change events for a particular SQL Server database or cluster:

  1. Enable the CDC on SQL Server to publish the CDC events in the database.

  2. Create a configuration file for the SQL Server connector.

When the connector starts, it will grab a consistent snapshot of the schemas in your SQL Server database and start streaming changes, producing events for every inserted, updated, and deleted row. You can also choose to produce events for a subset of the schemas and tables. Optionally ignore, mask, or truncate columns that are sensitive, too large, or not needed.

Following is an example of the configuration for a connector instance that monitors a SQL Server server at port 1433 on 192.168.99.100, which we logically name fullfillment. Typically, you configure the Debezium SQL Server connector in a .json file using the configuration properties available for the connector.

  1. {
  2. "name": "inventory-connector", (1)
  3. "config": {
  4. "connector.class": "io.debezium.connector.sqlserver.SqlServerConnector", (2)
  5. "database.hostname": "192.168.99.100", (3)
  6. "database.port": "1433", (4)
  7. "database.user": "sa", (5)
  8. "database.password": "Password!", (6)
  9. "database.dbname": "testDB", (7)
  10. "database.server.name": "fullfillment", (8)
  11. "table.whitelist": "dbo.customers", (9)
  12. "database.history.kafka.bootstrap.servers": "kafka:9092", (10)
  13. "database.history.kafka.topic": "dbhistory.fullfillment" (11)
  14. }
  15. }
1The name of our connector when we register it with a Kafka Connect service.
2The name of this SQL Server connector class.
3The address of the SQL Server instance.
4The port number of the SQL Server instance.
5The name of the SQL Server user
6The password for the SQL Server user
7The name of the database to capture changes from.
8The logical name of the SQL Server instance/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 Connector is used.
9A list of all tables whose changes Debezium should capture.
10The list of Kafka brokers that this connector will use to write and recover DDL statements to the database history topic.
11The name of the database history topic where the connector will write and recover DDL statements. This topic is for internal use only and should not be used by consumers.

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

This configuration can be sent via POST to a running Kafka Connect service, which will then record the configuration and start up the one connector task that will connect to the SQL Server database, read the transaction log, and record events to Kafka topics.

Monitoring

Kafka, Zookeeper, and Kafka Connect all have built-in support for JMX metrics. The SQL Server connector also publishes a number of metrics about the connector’s activities that can be monitored through JMX. The connector has two types of metrics. Snapshot metrics help you monitor the snapshot activity and are available when the connector is performing a snapshot. Streaming metrics help you monitor the progress and activity while the connector reads CDC table data.

Snapshot Metrics

MBean: debezium.sql_server:type=connector-metrics,context=snapshot,server=<database.server.name>
Attribute NameTypeDescription

LastEvent

string

The last snapshot event that the connector has read.

MilliSecondsSinceLastEvent

long

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

TotalNumberOfEventsSeen

long

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

NumberOfEventsFiltered

long

The number of events that have been filtered by whitelist or blacklist filtering rules configured on the connector.

MonitoredTables

string[]

The list of tables that are monitored by the connector.

QueueTotalCapcity

int

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

QueueRemainingCapcity

int

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

TotalTableCount

int

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

RemainingTableCount

int

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

SnapshotRunning

boolean

Whether the snapshot was started.

SnapshotAborted

boolean

Whether the snapshot was aborted.

SnapshotCompleted

boolean

Whether the snapshot completed.

SnapshotDurationInSeconds

long

The total number of seconds that the snapshot has taken so far, even if not complete.

RowsScanned

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.

Streaming Metrics

MBean: debezium.sql_server:type=connector-metrics,context=streaming,server=<database.server.name>
Attribute NameTypeDescription

LastEvent

string

The last streaming event that the connector has read.

MilliSecondsSinceLastEvent

long

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

TotalNumberOfEventsSeen

long

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

NumberOfEventsFiltered

long

The number of events that have been filtered by whitelist or blacklist filtering rules configured on the connector.

MonitoredTables

string[]

The list of tables that are monitored by the connector.

QueueTotalCapcity

int

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

QueueRemainingCapcity

int

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

Connected

boolean

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

MilliSecondsBehindSource

long

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

NumberOfCommittedTransactions

long

The number of processed transactions that were committed.

SourceEventPosition

map<string, string>

The coordinates of the last received event.

LastTransactionId

string

Transaction identifier of the last processed transaction.

Schema History Metrics

MBean: debezium.sql_server:type=connector-metrics,context=schema-history,server=<database.server.name>
Attribute NameTypeDescription

Status

string

One of STOPPED, RECOVERING (recovering history from the storage), RUNNING describing state of the database history.

RecoveryStartTime

long

The time in epoch seconds at what recovery has started.

ChangesRecovered

long

The number of changes that were read during recovery phase.

ChangesApplied

long

The total number of schema changes applie during recovery and runtime.

MilliSecondsSinceLastRecoveredChange

long

The number of milliseconds that elapsed since the last change was recovered from the history store.

MilliSecondsSinceLastAppliedChange

long

The number of milliseconds that elapsed since the last change was applied.

LastRecoveredChange

string

The string representation of the last change recovered from the history store.

LastAppliedChange

string

The string representation of the last applied change.

Connector properties

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

PropertyDefaultDescription

name

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

connector.class

The name of the Java class for the connector. Always use a value of io.debezium.connector.sqlserver.SqlServerConnector for the SQL Server connector.

tasks.max

1

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

database.hostname

IP address or hostname of the SQL Server database server.

database.port

1433

Integer port number of the SQL Server database server.

database.user

Username to use when connecting to the SQL Server database server.

database.password

Password to use when connecting to the SQL Server database server.

database.dbname

The name of the SQL Server database from which to stream the changes

database.server.name

Logical name that identifies and provides a namespace for the particular SQL Server database server being monitored. The logical name should be unique across all other connectors, since it is used as a prefix for all Kafka topic names emanating from this connector. Only alphanumeric characters and underscores should be used.

database.history.kafka.topic

The full name of the Kafka topic where the connector will store the database schema history.

database.history​.kafka.bootstrap.servers

A list of host/port pairs that the connector will use for establishing an initial connection to the Kafka cluster. This connection is used for retrieving database schema history previously stored by the connector, and for writing each DDL statement read from the source database. This should point to the same Kafka cluster used by the Kafka Connect process.

table.whitelist

An optional comma-separated list of regular expressions that match fully-qualified table identifiers for tables to be monitored; any table not included in the whitelist is excluded from monitoring. Each identifier is of the form schemaName.tableName. By default the connector will monitor every non-system table in each monitored schema. May not be used with table.blacklist.

table.blacklist

An optional comma-separated list of regular expressions that match fully-qualified table identifiers for tables to be excluded from monitoring; any table not included in the blacklist is monitored. Each identifier is of the form schemaName.tableName. May not be used with table.whitelist.

column.blacklist

empty string

An optional comma-separated list of regular expressions that match the fully-qualified names of columns that should be excluded from change event message values. Fully-qualified names for columns are of the form schemaName.tableName.columnName. Note that primary key columns are always included in the event’s key, also if blacklisted from the value.

time.precision.mode

adaptive

Time, date, and timestamps can be represented with different kinds of precision, including: adaptive (the default) 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; or connect always represents time and timestamp values using Kafka Connect’s built-in representations for Time, Date, and Timestamp, which uses millisecond precision regardless of the database columns’ precision. See temporal values.

tombstones.on.delete

true

Controls whether a tombstone event should be generated after a delete event.
When true the delete operations are represented by a delete event and a subsequent tombstone event. When false only a delete event is sent.
Emitting the tombstone event (the default behavior) allows Kafka to completely delete all events pertaining to the given key once the source record got deleted.

column.truncate.to.length.chars

n/a

An optional comma-separated list of regular expressions that match the fully-qualified names of character-based columns whose values should be truncated in the change event message values if the field values are longer than the specified number of characters. Multiple properties with different lengths can be used in a single configuration, although in each the length must be a positive integer. Fully-qualified names for columns are of the form databaseName.tableName.columnName, or databaseName.schemaName.tableName.columnName.

column.mask.with.length.chars

n/a

An optional comma-separated list of regular expressions that match the fully-qualified names of character-based columns whose values should be replaced in the change event message values with a field value consisting of the specified number of asterisk (*) characters. Multiple properties with different lengths can be used in a single configuration, although in each the length must be a positive integer or zero. Fully-qualified names for columns are of the form databaseName.tableName.columnName, or databaseName.schemaName.tableName.columnName.

column.propagate.source.type

n/a

An optional comma-separated list of regular expressions that match the fully-qualified names of columns whose original type and length should be added as a parameter to the corresponding field schemas in the emitted change messages. The schema parameters debezium.source.column.type, debezium.source.column.length and __debezium.source.column.scale is used to propagate the original type name and length (for variable-width types), respectively. Useful to properly size corresponding columns in sink databases. Fully-qualified names for columns are of the form schemaName.tableName.columnName.

message.key.columns

empty string

A semi-colon list of regular expressions that match fully-qualified tables and columns to map a primary key.
Each item (regular expression) must match the fully-qualified <fully-qualified table>:<a comma-separated list of columns> representing the custom key.
Fully-qualified tables could be defined as DB_NAME.TABLE_NAME or SCHEMA_NAME.TABLE_NAME, depending on the specific connector.

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

PropertyDefaultDescription

snapshot.mode

initial

A mode for taking an initial snapshot of the structure and optionally data of captured tables. Once the snapshot is complete, the connector will continue reading change events from the database’s redo logs.

Supported values are:
initial: Takes a snapshot of structure and data of captured tables; useful if topics should be populated with a complete representation of the data from the captured tables.
schema_only: Takes a snapshot of the structure of captured tables only; useful if only changes happening from now onwards should be propagated to topics.
initial_schema_only: This is equivalent to schema_only.
This option is deprecated and will be removed in a future release.

snapshot.isolation.mode

repeatable_read

Mode to control which transaction isolation level is used and how long the connector locks the monitored tables. There are five possible values: read_uncommitted, read_committed, repeatable_read, snapshot, and exclusive ( in fact, exclusive mode uses repeatable read isolation level, however, it takes the exclusive lock on all tables to be read).

It is worth documenting that snapshot, read_committed and read_uncommitted modes do not prevent other transactions from updating table rows during initial snapshot, while exclusive and repeatable_read do.

Another aspect is data consistency. Only exclusive and snapshot modes guarantee full consistency, that is, initial snapshot and streaming logs constitute a linear history. In case of repeatable_read and read_committed modes, it might happen that, for instance, a record added appears twice - once in initial snapshot and once in streaming phase. Nonetheless, that consistency level should do for data mirroring. For read_uncommitted there are no data consistency guarantees at all (some data might be lost or corrupted).

event.processing​.failure.handling.mode

fail

Specifies how the connector should react to exceptions during processing of events. fail will propagate the exception (indicating the offset of the problematic event), causing the connector to stop.
warn will cause the problematic event to be skipped and the offset of the problematic event to be logged.
skip will cause the problematic event to be skipped.

poll.interval.ms

1000

Positive integer value that specifies the number of milliseconds the connector should wait during each iteration for new change events to appear. Defaults to 1000 milliseconds, or 1 second.

max.queue.size

8192

Positive integer value that specifies the maximum size of the blocking queue into which change events read from the database log are placed before they are written to Kafka. This queue can provide backpressure to the CDC table reader when, for example, writes to Kafka are slower or if Kafka is not available. Events that appear in the queue are not included in the offsets periodically recorded by this connector. Defaults to 8192, and should always be larger than the maximum batch size specified in the max.batch.size property.

max.batch.size

2048

Positive integer value that specifies the maximum size of each batch of events that should be processed during each iteration of this connector. Defaults to 2048.

heartbeat.interval.ms

0

Controls how frequently heartbeat messages are sent.
This property contains an interval in milli-seconds that defines how frequently the connector sends messages into a heartbeat topic. This can be used to monitor whether the connector is still receiving change events from the database. You also should leverage heartbeat messages in cases where only records in non-captured tables are changed for a longer period of time. In such situation the connector would proceed to read the log from the database but never emit any change messages into Kafka, which in turn means that no offset updates are committed to Kafka. This may result in more change events to be re-sent after a connector restart. Set this parameter to 0 to not send heartbeat messages at all.
Disabled by default.

heartbeat.topics.prefix

__debezium-heartbeat

Controls the naming of the topic to which heartbeat messages are sent.
The topic is named according to the pattern <heartbeat.topics.prefix>.<server.name>.

snapshot.delay.ms

An interval in milli-seconds that the connector should wait before taking a snapshot after starting up;
Can be used to avoid snapshot interruptions when starting multiple connectors in a cluster, which may cause re-balancing of connectors.

snapshot.fetch.size

2000

Specifies the maximum number of rows that should be read in one go from each table while taking a snapshot. The connector will read the table contents in multiple batches of this size. Defaults to 2000.

snapshot.lock.timeout.ms

10000

An integer value that specifies the maximum amount of time (in milliseconds) to wait to obtain table locks when performing a snapshot. If table locks cannot be acquired in this time interval, the snapshot will fail (also see snapshots).
When set to 0 the connector will fail immediately when it cannot obtain the lock. Value -1 indicates infinite waiting.

snapshot.select.statement.overrides

Controls which rows from tables are included in snapshot.
This property contains a comma-separated list of fully-qualified tables (SCHEMA_NAME.TABLE_NAME). Select statements for the individual tables are specified in further configuration properties, one for each table, identified by the id snapshot.select.statement.overrides.[SCHEMA_NAME].[TABLE_NAME]. The value of those properties is the SELECT statement to use when retrieving data from the specific table during snapshotting. A possible use case for large append-only tables is setting a specific point where to start (resume) snapshotting, in case a previous snapshotting was interrupted.
Note: This setting has impact on snapshots only. Events captured during log reading are not affected by it.

source.struct.version

v2

Schema version for the source block in CDC events; Debezium 0.10 introduced a few breaking
changes to the structure of the source block in order to unify the exposed structure across all the connectors.
By setting this option to v1 the structure used in earlier versions can be produced. Note that this setting is not recommended and is planned for removal in a future Debezium version.

sanitize.field.names

true when connector configuration explicitly specifies the key.converter or value.converter parameters to use Avro, otherwise defaults to false.

Whether field names are sanitized to adhere to Avro naming requirements. See Avro naming for more details.

database.server.timezone

Timezone of the server.

This is used to define the timezone of the transaction timestamp (ts_ms) retrieved from the server (which is actually not zoned). Default value is unset. Should only be specified when running on SQL Server 2014 or older and using different timezones for the database server and the JVM running the Debezium connector.
When unset, default behavior is to use the timezone of the VM running the Debezium connector. In this case, when running on on SQL Server 2014 or older and using different timezones on server and the connector, incorrect ts_ms values may be produced.
Possible values include “Z”, “UTC”, offset values like “+02:00”, short zone ids like “CET”, and long zone ids like “Europe/Paris”.

The connector also supports pass-through configuration properties that are used when creating the Kafka producer and consumer. Specifically, all connector configuration properties that begin with the database.history.producer. prefix are used (without the prefix) when creating the Kafka producer that writes to the database history, and all those that begin with the prefix database.history.consumer. are used (without the prefix) when creating the Kafka consumer that reads the database history upon connector startup.

For example, the following connector configuration properties can be used to secure connections to the Kafka broker:

In addition to the pass-through to the Kafka producer and consumer, the properties starting with database., e.g. database.applicationName=debezium are passed to the JDBC URL.

  1. database.history.producer.security.protocol=SSL
  2. database.history.producer.ssl.keystore.location=/var/private/ssl/kafka.server.keystore.jks
  3. database.history.producer.ssl.keystore.password=test1234
  4. database.history.producer.ssl.truststore.location=/var/private/ssl/kafka.server.truststore.jks
  5. database.history.producer.ssl.truststore.password=test1234
  6. database.history.producer.ssl.key.password=test1234
  7. database.history.consumer.security.protocol=SSL
  8. database.history.consumer.ssl.keystore.location=/var/private/ssl/kafka.server.keystore.jks
  9. database.history.consumer.ssl.keystore.password=test1234
  10. database.history.consumer.ssl.truststore.location=/var/private/ssl/kafka.server.truststore.jks
  11. database.history.consumer.ssl.truststore.password=test1234
  12. database.history.consumer.ssl.key.password=test1234

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