KNIME Database Extension Guide

After executing a DB node, you can inspect the result in the outport view by right clicking the node and selecting the outport to inspect at the bottom of the menu. For more information on how to execute a node, please refer to the Quickstart Guide.

The DB Session life cycle is managed by the Connector nodes. Executing a Connector node will create a DB Session, and resetting the node or closing the workflow will destroy the corresponding DB Session and with it the connection to the database.

To close a DB Session during workflow execution the DB Connection Closer node can be used. This is also the preferred way to free up database resources as soon as they are no longer needed by the workflow. To close a DB Session simply connect it to the DB Connection Closer node which destroys the DB Session and with it the connection to the database as soon as it is executed. Use the input flow variable port of the DB Connection Closer node to executed it once it is save to destroy the DB Session.

As previously mentioned, the dedicated database-specific connector nodes already contain the necessary JDBC drivers. However, some databases require special licensing that prevents us from automatically installing or even bundling the necessary JDBC drivers with the corresponding connector nodes. For example, KNIME provides additional plug-ins to install the Oracle Database driver, official Microsoft SQL Server driver or the Amazon Redshift driver which require special licenses.

To install the plug-ins, go to File → Install KNIME Extensions…​. In the Install window, search for the driver that you need (Oracle, MS SQL Server or Redshift), and you will see something similar to the figure below. Then select the plug-in to install it. If you don’t see the plug-in in this window then it is already installed. After installing the plug-in, restart KNIME. After that, when you open the configuration dialog of the dedicated Connector node, you should see that the installed driver of the respective database is available in the driver name list.

When registering a JDBC driver, you need to specify its JDBC URL template, which will be used by the dedicated Connector node to create the final database URL. For example, jdbc:oracle:thin:@<host>:<port>/<database> is a valid driver URL template for the Oracle thin driver. For most databases you don’t have to find the suitable URL template by yourself, because the URL Template syntax information provides at least one URL template example for a database.

The values of the variables in the URL template, e.g <host>, <port>, or <database> can be specified in the configuration dialog of the corresponding Connector node.

Tokens:

For server-based databases, the following tokens are expected:

For file-based databases, the following tokens are expected:

Below is a selected list of common database drivers you can add among others to KNIME Analytics Platform:

The JDBC parameters allow you to define custom JDBC driver connection parameter. The value of a parameter can be a constant, variable, credential user, credential password or KNIME URL. For more information about the supported connection parameter please refer to your database vendor.

The figure below shows an example of SSL JDBC parameters with different variable types. You can set a boolean value to enable or disable SSL, you can also use a KNIME relative URL to point to the SSLTrustStore location, or use a credential input for the trustStorePassword parameter.

The settings in the Advanced tab allow you to define KNIME framework properties such as connection handling, advanced SQL dialect settings or query logging options. This is the place where you can tweak how KNIME interacts with the database e.g. how the queries should be created that are send to the database. In the Metadata section you can also disable the metadata fetching during configuration of a node or alter the timeout when doing so which might be necessary if you are connected to a database that needs more time to compute the metadata of a created query or you are connected to it via a slow network.

The full available options are described as follow:

Connection

Dialect capabilities

Dialect syntax

JDBC logger

JDBC parameter

JDBC statement cancellation

Metadata

Transaction

Misc

Dedicated DB connectors (e.g. Microsoft SQL Server Connector) and built-in drivers usually show only a subset of the above mentioned options since most options are predefined, such as whether the database supports CASE statements, etc.

The first step is to install the Oracle Database JDBC driver which is provided as a separate plug-in due to license restrictions. Please refer to Third-party Database Driver Plug-in for more information about the plug-in and how to install it.

Once the driver is installed you can use the dedicated Oracle Connector node. Please refer to Connecting to predefined databases on how to connect using dedicated Connector nodes.

To connect to Databricks, you need to install the KNIME Databricks Integration.

The next step is to download the Databricks Simba JDBC driver from the official website to your machine. Then go to File → Preferences → KNIME → Databases, and click Add.

In the new database driver window, provide the following information:

After filling all the information, click Ok, and the newly added driver will appear in the database driver preferences table. Click Apply and Close to apply the changes.

To connect to Databricks, you need to first create a Databricks environment that is connected to an existing Databricks cluster. To do this, use the Create Databricks Environment node. In the configuration window, you need to provide:

In the DB Port → Driver tab, you can select the driver name, which in this case is the Databricks Simba JDBC driver we have registered previously.

For the authentication, Databricks strongly recommends using tokens. Please refer to the authentication in Databricks AWS or Azure documentation for more information about personal access token.

To connect to BigQuery, you need to install the KNIME BigQuery Extension.

Due to license restrictions the BigQuery JDBC driver is not part of KNIME Analytics Platform and needs to be downloaded and registered separately. To download the BigQuery JDBC driver please visit the official website. Then go to File → Preferences → KNIME → Databases, and click Add.

In the new database driver window, provide the following information:

After filling all the information, click Ok, and the newly added driver will appear in the database driver preferences table. Click Apply and Close to apply the changes.

To connect to the BigQuery server, we suggest to use the Google Authentication (API Key) node to authenticate and create a connection to the Google APIs, and then the Google BigQuery Connector node to connect to BigQuery. As an alternative you can also specify the driver specific authentication information via the JDBC Parameters tab.

In the configuration window of the Google Authentication (API Key) node, you need to provide:

After the connection is successfully established, it can be used as the input Google Service Connection for the Google BigQuery Connector node. The configuration window contains as follows:

The dedicated Microsoft SQL Server Connector node is bundled by default with the jTDS for Microsoft SQL Server driver. If you want to use the official driver for Microsoft SQL Server instead, KNIME provides an additional plug-in to install the driver. Please refer to Third-party Database Driver Plug-in for more information about the plug-in and how to install it.

It is also possible to use your own Microsoft SQL Server driver. To register your own driver please refer to the Register your own JDBC drivers section. However, the Microsoft SQL Server driver might require several native libraries, such as DLLs. In that case you need to copy all the required native libraries into a single folder and then register this folder via the Add directory button in addition to the JDBC .jar file in the database driver window. This step is not required if you use the provided jTDS for Microsoft SQL Server driver or the official driver for Microsoft SQL Server installed through the plug-in.

After installing the JDBC driver, you can use the Microsoft SQL Server Connector node to start connecting to Microsoft SQL Server. Please refer to Connecting to predefined databases for more information on how to connect using dedicated Connector nodes.

Microsoft SQL Server supports the so-called Windows native authentication mode. If you want to use this mode, simply select None/native authentication in the Authentication setting in the configuration window. The following sections explain how to use this mode depending on which driver you use.

You can use the dedicated Microsoft SQL Server Connector node to connect to a dedicated SQL pool or serverless SQL pool in Azure Synapse Analytics. Before connecting you need to install the official driver for Microsoft SQL Server that is provided as an additional plug-in. Please refer to Third-party Database Driver Plug-in for more information about the plug-in and how to install it. It is also possible to use your own Microsoft SQL Server driver. To register your own driver please refer to the Register your own JDBC drivers section.

To connect you need to obtain the serverless and/or dedicated SQL endpoint and a login user e.g. the SQL administration user first. This information is available via the Synapse workspace view in Azure Portal.

Once you have the official driver installed and all necessary information available you can configure the Microsoft SQL Server Connector node. To do so open the node dialog and enter the serverless or dedicated SQL endpoint as hostname with master as default database. Enter the login information into the authentication section as shown below. Instead of a username and password you can also use Microsoft Entra ID login if this is configured in your Synapse workspace using the Microsoft Authentication node and the dynamic input port of the Microsoft SQL Server Connector.

In addition you need to specify the following JDBC parameters via the JDBC Parameters tab:

For more details about the JDBC parameters see the Microsoft documentation.

Finally, for serverless SQL pools you need to disabled transaction since they are not support via the Advanced Tab by unselecting the Enabled value in the Transaction section.

To connect to Hive, you need to install the KNIME Big Data Connectors Extension.

The dedicated Hive Connector node is bundled by default with the open-source Apache Hive JDBC driver. Proprietary drivers are also supported, but need to be registered first, such as the Hive JDBC connector provided by Cloudera.

In this example we want to connect to Hive using the proprietary Cloudera Hive JDBC driver. The first step is to download the latest Hive JDBC driver for Cloudera Enterprise. Then go to File → Preferences → KNIME → Databases, and click Add.

In the new database driver window, provide the following information:

Finally, click Ok and the newly added driver will appear in the database driver preferences table. Click Apply and Close to apply the changes and you can start connecting to your Hive database.

Hive has a dedicated Connector node called Hive Connector, please refer to Connecting to predefined databases on how to connect using dedicated Connector nodes.

To connect to Apache Impala, you need to install the KNIME Big Data Connectors Extension.

The dedicated Impala Connector node is bundled by default with the open-source Apache Hive JDBC driver, which is compatible with Impala. Proprietary drivers are also supported, but need to be registered first, such as the Impala JDBC connector provided by Cloudera.

In this example we want to connect to Impala using the proprietary Cloudera Impala JDBC driver. The first step is to download the latest Impala JDBC driver for Cloudera Enterprise. Then go to File → Preferences → KNIME → Databases, and click Add.

In the new database driver window, provide the following information:

Finally, click Ok and the newly added driver will appear in the database driver preferences table. Click Apply and Close to apply the changes and you can start connecting to your Impala database.

Impala has a dedicated Connector node called Impala Connector, please refer to Connecting to predefined databases on how to connect using dedicated Connector nodes.

After selecting the table, you can start working with the data. First we use the DB Row Filter node to filter rows according to certain conditions. The figure above shows the configuration dialog of the DB Row Filter. On the left side there is a Preview area that lists all conditions of the filter to apply to the input data. Filters can be combined and grouped via logical operators such as AND or OR. Only rows that fulfil the specified filter conditions will be kept in the output data table. At the bottom there are options to:

To create a new condition click on the Add_Condition button. To edit a condition select in the condition list which will show the selected condition in the condition editor on the right. The editor consists of at least two dropdown lists. The most left one contains the columns from the input data table, and the one next to it contains the operators that are compatible with the selected column type, such as =, !=, <, >. Depending on the selected operation a third and maybe fourth input field will be displayed to enter or select the filter values. The button next to the values fields fetches all possible values for the selected column which will then be available for selection in the value field.

Clicking on a logical operator in the Preview list would allow you to switch between AND or OR, and to delete this operator by clicking Ungroup.

As in our example, we want to return all rows that fulfil the following conditions:

The next step is to calculate the average air time to each unique destination airport using the DB GroupBy node. To retrieve the number of rows per group tick the Add Count(*) checkbox in the Advanced Settings. The name of the group count column can be changed via the result column name field.

To calculate the average air time for each destination airport, we need to group by the Dest column in the Groups tab, and in Manual Aggregation tab we select the ActualElapsedTime column (air time) and AVG as the aggregation method.

To join the result back to the original data, we use the DB Joiner node, which joins two database tables based on joining column(s) of both tables. In the Joiner settings tab, there are options to choose the join mode, whether Inner Join, Full Outer Join, etc, and the joining column(s).

In the Column Selection tab you can select which columns from each of the table you want to include in the output table. By default the joining columns from bottom input will not show up in the output table.

The DB Query node modifies the input SQL query from an incoming database data connection. The SQL query from the predecessor is represented by the place holder #table# and will be replaced during execution. The modified input query is then available at the outport.

Executes an entered SQL query and returns the result as KNIME data table. This node does not alter or wrap the query and thus supports all kinds of statements that return data.

This node allows you to execute a SQL query with different parameters. It loops over the input KNIME table and takes the values from the input table to parameterise the input SQL query. Since the node has a KNIME data table input it provides a type mapping tab that allows you to change the mapping rules. For more information on the Type Mapping tab, please refer to the Type Mapping section.

This node runs SQL queries in the connected database restricted by the possible values given by the input table. It restricts each SQL query so that only rows that match the possible values from the input table are retrieved whereas the number of values per query can be defined. This node is usually used to execute IN queries e.g.

During execution, the column placeholder $Col1_values$ will be replaced by a comma separated list of values from the input table. Since the node has a KNIME data table input it provides a type mapping tab that allows you to change the mapping rules. For more information on the Type Mapping tab, please refer to the Type Mapping section.

An example of the usage of this node is available on KNIME Hub.

This node deletes rows from a selected table in the database. The input is a DB Connection port that describes the database, and also a KNIME data table containing the values which define which rows to delete from the database. It deletes data rows in the database based on the selected columns from the input table. Therefore all selected column names need to exactly match the column names inside the database. Only the rows in the database table that match the value combinations of the selected columns from the KNIME input data table will be deleted.

The figure below shows the configuration dialog of the DB Delete (Table) node. The configuration dialog of the other nodes for DB Manipulation are very similar. You can enter the table name and its corresponding schema or select the table name in the Database Metadata Browser by clicking Select a table.

In addition the identification columns from the input table need to be selected. The names of the selected KNIME table columns have to match the names in the selected database table. All rows in the database table with matching values for the selected columns from the input KNIME data table will be deleted. In SQL this is equivalent to the WHERE columns. There are three options:

The Output Type Mapping tab allows you to define mapping rules from KNIME types to database types. For more information on this, please refer to the Type Mapping section.

This node deletes rows from a selected table in the database that match the specified filter conditions. The input is a DB Connection port that can be exchanged to a DB Data port. In both cases the input port describes the database. The output port can be exchanged from a DB Connection to a DB Data port as well.

In the node dialog of the DB Delete (Filter) node you can enter the table name and its corresponding schema or select the table name in the Database Metadata Browser by clicking Select a table. In addition you can specify the filter conditions that are used to identify the rows in the database table that should be deleted. The conditions are used to generate the WHERE clause of the DELETE statement. All rows that match the filter conditions will be deleted.

For example, the settings specified in the figure shown below will delete all rows from the flights table that took place prior the Year 2017 and that where neither Diverted nor Cancelled.

An example of the usage of this node is available on KNIME Hub.

The DB Transaction Start node starts a transaction using the input database connection. As long as the transaction is in process, the input database connection cannot be used outside of the transaction. Depending on the isolation level, other connections might not see any changes in the database while the transaction is in process. The transaction uses the default isolation level of the connected database.

The DB Transaction End node ends the transaction of the input database connection. The node ends the transaction with a commit that makes all changes visible to other users if executed successfully. Otherwise the node ends the transaction with a rollback returning the database to the state at the beginning of the transaction.

This node has 2 input ports. The first one is the transactional DB connection port which should be connected to from the end of the transaction chain. The second port should contain the transactional DB connection from the output of the DB Transaction Start node. If the transaction is successful and a commit is executed, the DB connection from the first input port will be forwarded to the output port, otherwise in case of a rollback, the DB connection from the second input port will be forwarded.

The figure below shows an example of the transaction nodes. In this example, the transaction consists of two DB Writer nodes that write data to the same table consecutively. If an error occurs during any step of the writing, the changes will not be executed and the database will be returned to the previous state at the beginning of the transaction. If no error occurs, the changes to the database will be commited.

If you don’t want to migrate and want to disable the migration message, click on Disable this message in the message. The Preferences → Databases page will open where you can uncheck the option Offer the migration of workflows that contain deprecated database nodes as shown in the figure below. Click Apply and Close to save the setting and the message will not appear anymore if you open a workflow containing deprecated database nodes. To reverse this setting, simply open Preferences → Databases page again and enable the check box.

KNIME Analytics Platform clients need to be made aware of a customization profile so that they can request it from KNIME Server. Please consult the respective section of the KNIME Server Administration Guide for a complete reference on how to set this up.

In KNIME Analytics Platform, you can go to File → Preferences → KNIME → Customization Profiles. This opens the Customization Profiles page where you can choose which KNIME Server and profile to use. The changes will take effect after restarting KNIME Analytics Platform.

To see whether the driver has been added, go to File → Preferences → KNIME → Databases. In this page, drivers that are added via a customization profile are marked as origin: profile after the driver ID (see figure below). These drivers can be edited but not deleted. To delete a profile driver, please go to the Customization Profiles page and unselect the respective profile.

Default JDBC Parameters provide a way for hub admins to inject JDBC parameters on JDBC connections made from workflows running on KNIME Hub. Depending on the database a different parameter and value is used to perform constrained delegation. Some drivers only require the name of the user that should be impersonated. This can be done using the name of the KNIME Hub user that executes the workflow (context.workflow.username) as the value of the driver specific property. See Hive or Impala for an example. Other drivers require the delegated GSS credential as parameter which can automatically be passed to the driver via the value type DELEGATED_GSS_CREDENTIAL. The GSS credential is obtained using the MS-SFU Kerberos 5 Extension. See Microsoft SQL Server for an example.

If the driver does not provide a dedicated parameter to do constrained delegation the KNIME Executor can request a Kerberos service ticket on behalf of the user that executes the workflow using the MS-SFU Kerberos 5 Extension. The obtained service ticket is then used by the JDBC driver when establishing the connection to the database.

To request the service ticket the KNIME Executor requires the service name and the fully qualified hostname. To specify the service name add the following line to the .epf file of your KNIME Executors customization profile:

Whereas <VALUE> is the name of the service to request the Kerberos ticket for. See PostgreSQL for an example.

The fully qualified hostname is automatically extracted from the hostname setting for all dedicated connector nodes. For the generic DB Connector node the name is extracted from the JDBC connection string using a default regular expression (.*(?:@|/)([^:;,/\\]*).*) that should work out of the box for most JDBC strings. However if necessary it can be changed by adding the following line to the .epf file of your KNIME Executors customization profile:

The <VALUE> should contain a regular expression that extracts the fully qualified hostname from the JDBC URL with the first group matching the hostname.

The connection initialization statement provides a way for Hub admins to inject a SQL statement that is executed when a JDBC connection is created from a workflow running on KNIME Hub. This function can be used for constrained delegation in some databases such as Exasol by executing a specific SQL statement with the context.workflow.username as variable e.g.

This example sets up the Hive JDBC driver (embedded or proprietary) so that KNIME Hub will impersonate workflow users on JDBC connections.

Activating user impersonation on Hive depends on the used JDBC driver:

The SQL Server JDBC driver from Microsoft requires some special licensing that you need to agree to. That is why KNIME provides an additional plug-in to install the driver. In order to install the plug-in follow the steps as described in the Third-party Database Driver Plug-in section.

If you use Kerberos based authentication for Microsoft SQL Server, we recommend to also setup user impersonation. This example sets up the Microsoft SQL Server JDBC driver so that KNIME Hub will impersonate workflow users on JDBC connections. For further details about using Kerberos integrated authentication with Microsoft SQL Server see the Microsoft SQL Server documentation.

Activate the user impersonation for the embedded Microsoft SQL Server driver, by adding the following line to the KNIME Hub preferences file.

In the Microsoft SQL Server Connector ensure that you have selected Kerberos in the Authentication setting in the configuration window and added the following two parameters to the JDBC Parameters tab:

These parameters can be set automatically as Default JDBC Parameters via the KNIME Hub preferences file by adding the following lines:

For further details about the parameters that are used for constrained delegation see the Microsoft SQL Server documentation.

The Oracle Database JDBC driver requires some special licensing that you need to agree to. That is why KNIME provides an additional plug-in to install the driver. In order to install the plug-in follow the steps as described in the Third-party Database Driver Plug-in section.

If you use Kerberos based authentication for Oracle Database, we recommend to also setup constrained delegation.

Activate the Kerberos constrained delegation for the installed Oracle driver by adding the following lines to the KNIME Hub preferences file (e.g. oracle.epf).

The service name itself is not used so any non-empty string will enable constrained delegation.