Chapter 4. Configuration

Table of Contents

4.1. Node Properties
4.2. Node
4.3. Node Group
4.4. Node Group Link
4.5. Channel
4.6. Triggers and Routers
4.6.1. Trigger
4.6.1.1. Large Objects
4.6.1.2. External Select
4.6.2. Router
4.6.2.1. Default Router
4.6.2.2. Column Match Router
4.6.2.3. Lookup Table Router
4.6.2.4. Subselect Router
4.6.2.5. Scripted Router
4.6.2.6. Audit Table Router
4.6.2.7. Utilizing External Select when Routing
4.6.3. Trigger / Router Mappings
4.6.3.1. Initial Loads
4.6.3.2. Dead Triggers
4.6.3.3. Enabling "Ping Back"
4.7. Opening Registration
4.8. Transforming Data
4.8.1. Transform Configuration Tables
4.8.2. Transformation Types
4.9. Data Load Filters
4.9.1. Load Filter Configuration Table
4.9.2. Variables available to Data Load Filters
4.9.3. Data Load Filter Example
4.10. Conflict Detection and Resolution

Chapter 3 introduced numerous concepts and the analysis and design needed to create an implementation of SymmetricDS. This chapter re-visits each analysis step and documents how to turn a SymmetricDS design into reality through configuration of the various SymmetricDS tables. In addition, several advanced configuration options, not presented previously, will also be covered.

4.1. Node Properties

To get a SymmetricDS node running, it needs to be given an identity and it needs to know how to connect to the database it will be synchronizing. The preferred way to configure a SymmetricDS engine is to create a properties file in the engines directory. The SymmetricDS server will create an engine for each properties file found in the engines directory. When started up, SymmetricDS reads the synchronization configuration and state from the database. If the configuration tables are missing, they are created automatically (auto creation can be disabled). Basic configuration is described by inserting into the following tables (the complete data model is defined in Appendix A, Data Model).

  • NODE_GROUP - specifies the tiers that exist in a SymmetricDS network

  • NODE_GROUP_LINK - links two node groups together for synchronization

  • CHANNEL - grouping and priority of synchronizations

  • TRIGGER - specifies tables, channels, and conditions for which changes in the database should be captured

  • ROUTER - specifies the routers defined for synchronization, along with other routing details

  • TRIGGER_ROUTER - provides mappings of routers and triggers

During start up, triggers are verified against the database, and database triggers are installed on tables that require data changes to be captured. The Route, Pull and Push Jobs begin running to synchronize changes with other nodes.

Each node requires properties that allow it to connect to a database and register with a parent node. Properties are configured in a file named xxxxx.properties that is placed in the engines directory of the SymmetricDS install. The file is usually named according to the engine.name, but it is not a requirement.

To give a node its identity, the following properties are required. Any other properties found in conf/symmetric.properties can be overridden for a specific engine in an engine's properties file. If the properties are changed in conf/symmetric.properties they will take effect across all engines deployed to the server. Note that you can use the variable $(hostName) to represent the host name of the machine when defining these properties (for example, external.id=$(hostName) ).

engine.name

This is an arbitrary name that is used to access a specific engine using an HTTP URL. Each node configured in the engines directory must have a unique engine name. The engine name is also used for the domain name of registered JMX beans.

group.id

The node group that this node is a member of. Synchronization is specified between node groups, which means you only need to specify it once for multiple nodes in the same group.

external.id

The external id for this node has meaning to the user and provides integration into the system where it is deployed. For example, it might be a retail store number or a region number. The external id can be used in expressions for conditional and subset data synchronization. Behind the scenes, each node has a unique sequence number for tracking synchronization events. That makes it possible to assign the same external id to multiple nodes, if desired.

sync.url

The URL where this node can be contacted for synchronization. At startup and during each heartbeat, the node updates its entry in the database with this URL. The sync url is of the format: http://{hostname}:{port}/{webcontext}/sync/{engine.name}.

The {webcontext} is blank for a standalone deployment. It will typically be the name of the war file for an application server deployment.

The {engine.name} can be left blank if there is only one engine deployed in a SymmetricDS server.

When a new node is first started, it is has no information about synchronizing. It contacts the registration server in order to join the network and receive its configuration. The configuration for all nodes is stored on the registration server, and the URL must be specified in the following property:

registration.url

The URL where this node can connect for registration to receive its configuration. The registration server is part of SymmetricDS and is enabled as part of the deployment. This is typically equal to the value of the sync.url of the registration server.

Important

Note that a registration server node is defined as one whose registration.url is either (a) blank, or (b) identical to its sync.url.

For a deployment where the database connection pool should be created using a JDBC driver, set the following properties:

db.driver

The class name of the JDBC driver.

db.url

The JDBC URL used to connect to the database.

db.user

The database username, which is used to login, create, and update SymmetricDS tables.

db.password

The password for the database user.

4.2. Node

A node, a single instance of SymmetricDS, is defined in the NODE table. Two other tables play a direct role in defining a node, as well The first is NODE_IDENTITY. The only row in this table is inserted in the database when the node first registers with a parent node. In the case of a root node, the row is entered by the user. The row is used by a node instance to determine its node identity.

The following SQL statements set up a top-level registration server as a node identified as "00000" in the "corp" node group.

insert into SYM_NODE 
  (node_id, node_group_id, external_id, sync_enabled)
values
  ('00000', 'corp', '00000', 1);

insert into SYM_NODE_IDENTITY values ('00000');

The second table, NODE_SECURITY has rows created for each child node that registers with the node, assuming auto-registration is enabled. If auto registration is not enabled, you must create a row in NODE and NODE_SECURITY for the node to be able to register. You can also, with this table, manually cause a node to re-register or do a re-initial load by setting the corresponding columns in the table itself. Registration is discussed in more detail in Section 4.7, “Opening Registration”.

4.3. Node Group

Node Groups are straightforward to configure and are defined in the NODE_GROUP table. The following SQL statements would create node groups for "corp" and "store" based on our retail store example.

insert into SYM_NODE_GROUP 
  (node_group_id, description)
values
  ('store', 'A retail store node');

insert into SYM_NODE_GROUP 
  (node_group_id, description)
values
  ('corp', 'A corporate node');

4.4. Node Group Link

Similarly, Node Group links are established using a data event action of 'P' for Push and 'W' for Pull ("wait"). The following SQL statements links the "corp" and "store" node groups for synchronization. It configures the "store" nodes to push their data changes to the "corp" nodes, and the "corp" nodes to send changes to "store" nodes by waiting for a pull.

insert into SYM_NODE_GROUP_LINK
  (source_node_group, target_node_group, data_event_action)
values
  ('store', 'corp', 'P');

insert into SYM_NODE_GROUP_LINK
  (source_node_group, target_node_group, data_event_action)
values
  ('corp', 'store', 'W');

A node group link can be configured to use the same node group as the source and the target. This configuration allows a node group to sync with every other node in its group.

A third type of link action of 'R' for 'Route Only' exists if you want to associate a router with a link that will not move the data. This action type might be useful when using an XML publishing router or an audit table changes router.

4.5. Channel

By categorizing data into channels and assigning them to TRIGGERs, the user gains more control and visibility into the flow of data. In addition, SymmetricDS allows for synchronization to be enabled, suspended, or scheduled by channels as well. The frequency of synchronization and order that data gets synchronized is also controlled at the channel level.

The following SQL statements setup channels for a retail store. An "item" channel includes data for items and their prices, while a "sale_transaction" channel includes data for ringing sales at a register.

insert into SYM_CHANNEL 
  (channel_id, processing_order, max_batch_size, max_batch_to_send, 
   extract_period_millis, batch_algorithm, enabled, description)
values
  ('item', 10, 1000, 10,  0, 'default', 1, 'Item and pricing data');

insert into SYM_CHANNEL 
  (channel_id, processing_order, max_batch_size, max_batch_to_send, 
   extract_period_millis, batch_algorithm, enabled, description)
values
  ('sale_transaction', 1, 1000, 10,  60000, 'transactional', 1, 
   'retail sale transactions from register');

Batching is the grouping of data, by channel, to be transferred and committed at the client together. There are three different out-of-the-box batching algorithms which may be configured in the batch_algorithm column on channel.

default

All changes that happen in a transaction are guaranteed to be batched together. Multiple transactions will be batched and committed together until there is no more data to be sent or the max_batch_size is reached.

transactional

Batches will map directly to database transactions. If there are many small database transactions, then there will be many batches. The max_batch_size column has no effect.

nontransactional

Multiple transactions will be batched and committed together until there is no more data to be sent or the max_batch_size is reached. The batch will be cut off at the max_batch_size regardless of whether it is in the middle of a transaction.

If a channel contains only tables that will be synchronized in one direction and and data is routed to all the nodes in the target node groups, then batching on the channel can be optimized to share batches across nodes. This is an important feature when data needs to be routed to thousands of nodes. When this mode is detected, you will see batches created in OUTGOING_BATCH with the common_flag set to 1.

There are also several size-related parameters that can be set by channel. They include:

max_batch_size

Specifies the maximum number of data events to process within a batch for this channel.

max_batch_to_send

Specifies the maximum number of batches to send for a given channel during a 'synchronization' between two nodes. A 'synchronization' is equivalent to a push or a pull. For example, if there are 12 batches ready to be sent for a channel and max_batch_to_send is equal to 10, then only the first 10 batches will be sent even though 12 batches are ready.

max_data_to_route

Specifices the maximum number of data rows to route for a channel at a time.

Based on your particular synchronization requirements, you can also specify whether old, new, and primary key data should be read and included during routing for a given channel. These are controlled by the columns use_old_data_to_route, use_row_data_to_route, and use_pk_data_to_route, respectively. By default, they are all 1 (true).

Finally, if data on a particular channel contains big lobs, you can set the column contains_big_lob to 1 (true) to provide SymmetricDS the hint that the channel contains big lobs. Some databases have shortcuts that SymmetricDS can take advantage of if it knows that the lob columns in DATA aren't going to contain large lobs. The definition of how large a 'big' lob is varies from database to database.

4.6. Triggers and Routers

4.6.1. Trigger

SymmetricDS captures synchronization data using database triggers. SymmetricDS' Triggers are defined in the TRIGGER table. Each record is used by SymmetricDS when generating database triggers. Database triggers are only generated when a trigger is associated with a ROUTER whose source_node_group_id matches the node group id of the current node.

The source_table_name may contain the asterisk ('*') wildcard character so that one TRIGGER table entry can define synchronization for many tables. System tables and any tables that start with the SymmetricDS table prefix will be excluded. A list of wildcard tokens can also be supplied. If there are multiple tokens, they should be delimited with a comma. A wildcard token can also start with a bang ('!') to indicate an exclusive match. Tokens are always evalulated from left to right. When a table match is made, the table is either added to or removed from the list of tables. If another trigger already exists for a table, then that table is not included in the wildcard match (the explictly defined trigger entry take precendence).

When determining whether a data change has occurred or not, by defalt the triggers will record a change even if the data was updated to the same value(s) they were originally. For example, a data change will be captured if an update of one column in a row updated the value to the same value it already was. There is a global property, trigger.update.capture.changed.data.only.enabled (false by default), that allows you to override this behavior. When set to true, SymmetricDS will only capture a change if the data has truly changed (i.e., when the new column data is not equal to the old column data).

Important

The property trigger.update.capture.changed.data.only.enabled is currently only supported in the MySQL, DB2 and Oracle dialects.

The following SQL statement defines a trigger that will capture data for a table named "item" whenever data is inserted, updated, or deleted. The trigger is assigned to a channel also called 'item'.

insert into SYM_TRIGGER 
    (trigger_id,source_table_name,channel_id,last_update_time,create_time)
  values
    ('item', 'item', 'item', current_timestamp, current_timestamp);

Important

Note that many databases allow for multiple triggers of the same type to be defined. Each database defines the order in which the triggers fire differently. If you have additional triggers beyond those SymmetricDS installs on your table, please consult your database documentation to determine if there will be issues with the ordering of the triggers.

4.6.1.1. Large Objects

Two lobs-related settings are also available on TRIGGER:

use_stream_lobs

Specifies whether to capture lob data as the trigger is firing or to stream lob columns from the source tables using callbacks during extraction. A value of 1 indicates to stream from the source via callback; a value of 0, lob data is captured by the trigger.

use_capture_lobs

Provides a hint as to whether this trigger will capture big lobs data. If set to 1 every effort will be made during data capture in trigger and during data selection for initial load to use lob facilities to extract and store data in the database.

4.6.1.2. External Select

Occasionally, you may find that you need to capture and save away a piece of data present in another table when a trigger is firing. This data is typically needed for the purposes of determining where to 'route' the data to once routing takes place. Each trigger definition contains an optional external_select field which can be used to specify the data to be captured. Once captured, this data is available during routing in DATA's external_data field. For these cases, place a SQL select statement which returns the data item you need for routing in external_select. An example of the use of external select can be found in Section 4.6.2.7, “Utilizing External Select when Routing”.

4.6.2. Router

Routers provided in the base implementation currently include:

  • Default Router - a router that sends all data to all nodes that belong to the target node group defined in the router.
  • Column Match Router - a router that compares old or new column values to a constant value or the value of a node's external_id or node_id.
  • Lookup Router - a router which can be configured to determine routing based on an existing or ancillary table specifically for the purpose of routing data.
  • Subselect Router - a router that executes a SQL expression against the database to select nodes to route to. This SQL expression can be passed values of old and new column values.
  • Scripted Router - a router that executes a Bean Shell script expression in order to select nodes to route to. The script can use the the old and new column values.
  • Xml Publishing Router - a router the publishes data changes directly to a messaging solution instead of transmitting changes to registered nodes. This router must be configured manually in XML as an extension point.
  • Audit Table Router - a router that inserts into an automatically created audit table. It records captured changes to tables that it is linked to.

The mapping between the set of triggers and set of routers is many-to-many. This means that one trigger can capture changes and route to multiple locations. It also means that one router can be defined an associated with many different triggers.

4.6.2.1. Default Router

The simplest router is a router that sends all the data that is captured by its associated triggers to all the nodes that belong to the target node group defined in the router. A router is defined as a row in the ROUTER table. It is then linked to triggers in the TRIGGER_ROUTER table.

The following SQL statement defines a router that will send data from the 'corp' group to the 'store' group.

insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, 
    create_time, last_update_time)
values
  ('corp-2-store','corp', 'store', current_timestamp, current_timestamp);

The following SQL statement maps the 'corp-2-store' router to the item trigger.

insert into SYM_TRIGGER_ROUTER 
  (trigger_id, router_id, initial_load_order,  create_time, last_update_time)
values
  ('item', 'corp-2-store', 1, current_timestamp, current_timestamp);

4.6.2.2. Column Match Router

Sometimes requirements may exist that require data to be routed based on the current value or the old value of a column in the table that is being routed. Column routers are configured by setting the router_type column on the ROUTER table to column and setting the router_expression column to an equality expression that represents the expected value of the column.

The first part of the expression is always the column name. The column name should always be defined in upper case. The upper case column name prefixed by OLD_ can be used for a comparison being done with the old column data value.

The second part of the expression can be a constant value, a token that represents another column, or a token that represents some other SymmetricDS concept. Token values always begin with a colon (:).

Consider a table that needs to be routed to all nodes in the target group only when a status column is set to 'READY TO SEND.' The following SQL statement will insert a column router to accomplish that.

insert into SYM_ROUTER 
(router_id, source_node_group_id, target_node_group_id, router_type, 
 router_expression, create_time, last_update_time)
values
('corp-2-store-ok','corp', 'store', 'column', 
 'STATUS=READY TO SEND', current_timestamp, current_timestamp);

Consider a table that needs to be routed to all nodes in the target group only when a status column changes values. The following SQL statement will insert a column router to accomplish that. Note the use of OLD_STATUS, where the OLD_ prefix gives access to the old column value.

insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store-status','corp', 'store', 'column', 
    'STATUS!=:OLD_STATUS', current_timestamp, current_timestamp);

Consider a table that needs to be routed to only nodes in the target group whose STORE_ID column matches the external id of a node. The following SQL statement will insert a column router to accomplish that.

insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store-id','corp', 'store', 'column', 
    'STORE_ID=:EXTERNAL_ID', current_timestamp, current_timestamp);

Attributes on a NODE that can be referenced with tokens include:

  • :NODE_ID
  • :EXTERNAL_ID
  • :NODE_GROUP_ID

Captured EXTERNAL_DATA is also available for routing as a virtual column.

Consider a table that needs to be routed to a redirect node defined by its external id in the REGISTRATION_REDIRECT table. The following SQL statement will insert a column router to accomplish that.

insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store-redirect','corp', 'store', 'column', 
    'STORE_ID=:REDIRECT_NODE', current_timestamp, current_timestamp);

More than one column may be configured in a router_expression. When more than one column is configured, all matches are added to the list of nodes to route to. The following is an example where the STORE_ID column may contain the STORE_ID to route to or the constant of ALL which indicates that all nodes should receive the update.

insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store-multiple-matches','corp', 'store', 'column', 
   'STORE_ID=ALL or STORE_ID=:EXTERNAL_ID', current_timestamp, current_timestamp);

The NULL keyword may be used to check if a column is null. If the column is null, then data will be routed to all nodes who qualify for the update. This following is an example where the STORE_ID column is used to route to a set of nodes who have a STORE_ID equal to their EXTERNAL_ID, or to all nodes if the STORE_ID is null.

insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store-multiple-matches','corp', 'store', 'column', 
   'STORE_ID=NULL or STORE_ID=:EXTERNAL_ID', current_timestamp, current_timestamp);

4.6.2.3. Lookup Table Router

A lookup table may contain the id of the node where data needs to be routed. This could be an existing table or an ancillary table that is added specifically for the purpose of routing data. Lookup table routers are configured by setting the router_type column on the ROUTER table to lookuptable and setting a list of configuration parameters in the router_expression column.

Each of the following configuration parameters are required.

LOOKUP_TABLE

This is the name of the lookup table.

KEY_COLUMN

This is the name of the column on the table that is being routed. It will be used as a key into the lookup table.

LOOKUP_KEY_COLUMN

This is the name of the column that is the key on the lookup table.

EXTERNAL_ID_COLUMN

This is the name of the column that contains the external_id of the node to route to on the lookup table.

Note that the lookup table will be read into memory and cached for the duration of a routing pass for a single channel.

Consider a table that needs to be routed to a specific store, but the data in the changing table only contains brand information. In this case, the STORE table may be used as a lookup table.

insert into SYM_ROUTER 
(router_id, source_node_group_id, target_node_group_id, router_type, 
 router_expression, create_time, last_update_time)
values
('corp-2-store-ok','corp', 'store', 'lookuptable', 
 'LOOKUP_TABLE=STORE
KEY_COLUMN=BRAND_ID
LOOKUP_KEY_COLUMN=BRAND_ID
EXTERNAL_ID_COLUMN=STORE_ID', current_timestamp, current_timestamp);

4.6.2.4. Subselect Router

Sometimes routing decisions need to be made based on data that is not in the current row being synchronized. A 'subselect' router can be used in these cases. A 'subselect' is configured with a router_expression that is a SQL select statement which returns a result set of the node ids that need routed to. Column tokens can be used in the SQL expression and will be replaced with row column data. The overhead of using this router type is high because the 'subselect' statement runs for each row that is routed. It should not be used for tables that have a lot of rows that are updated. It also has the disadvantage that if the data being relied on to determine the node id has been deleted before routing takes place, then no results would be returned and routing would not happen.

The router_expression you specify is appended to the following SQL statement in order to select the node ids:

select c.node_id from sym_node c where 
  c.node_group_id=:NODE_GROUP_ID and c.sync_enabled=1 and ...

As you can see, you have access to information about the node currently under consideration for routing through the 'c' alias, for example c.external_id. There are two node-related tokens you can use in your expression:

  • :NODE_GROUP_ID
  • :EXTERNAL_DATA

Column names representing data for the row in question are prefixed with a colon as well, for example: :EMPLOYEE_ID, or :OLD_EMPLOYEE_ID. Here, the OLD_ prefix indicates the value before the change in cases where the old data has been captured.

For an example, consider the case where an Order table and a OrderLineItem table need to be routed to a specific store. The Order table has a column named order_id and STORE_ID. A store node has an external_id that is equal to the STORE_ID on the Order table. OrderLineItem, however, only has a foreign key to its Order of order_id. To route OrderLineItems to the same nodes that the Order will be routed to, we need to reference the master Order record.

There are two possible ways to solve this in SymmetricDS. One is to configure a 'subselect' router_type on the ROUTER table, shown below (The other possible approach is to use an external_select to capture the data via a trigger for use in a column match router, demonstrated in Section 4.6.2.7, “Utilizing External Select when Routing”).

Our solution utilizing subselect compares the external id of the current node with the store id from the Order table where the order id matches the order id of the current row being routed:

insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store','corp', 'store', 'subselect', 
    'c.external_id in (select STORE_ID from order where order_id=:ORDER_ID)', 
    current_timestamp, current_timestamp);

As a final note, please note in this example that the parent row in Order must still exist at the moment of routing for the child rows (OrderLineItem) to route, since the select statement is run when routing is occurring, not when the change data is first captured.

4.6.2.5. Scripted Router

When more flexibility is needed in the logic to choose the nodes to route to, then the a scripted router may be used. The currently available scripting language is Bean Shell. Bean Shell is a Java-like scripting language. Documentation for the Bean Shell scripting language can be found at http://www.beanshell.org.

The router_type for a Bean Shell scripted router is 'bsh'. The router_expression is a valid Bean Shell script that:

  • adds node ids to the targetNodes collection which is bound to the script
  • returns a new collection of node ids
  • returns a single node id
  • returns true to indicate that all nodes should be routed or returns false to indicate that no nodes should be routed

Also bound to the script evaluation is a list of nodes. The list of nodes is a list of eligible org.jumpmind.symmetric.model.Node objects. The current data column values and the old data column values are bound to the script evaluation as Java object representations of the column data. The columns are bound using the uppercase names of the columns. Old values are bound to uppercase representations that are prefixed with 'OLD_'.

If you need access to any of the SymmetricDS services, then the instance of org.jumpmind.symmetric.ISymmetricEngine is accessible via the bound engine variable.

In the following example, the node_id is a combination of STORE_ID and WORKSTATION_NUMBER, both of which are columns on the table that is being routed.


insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store-bsh','corp', 'store', 'bsh', 
    'targetNodes.add(STORE_ID + "-" + WORKSTATION_NUMBER);', 
    current_timestamp, current_timestamp);

The same could also be accomplished by simply returning the node id. The last line of a bsh script is always the return value.


insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store-bsh','corp', 'store', 'bsh', 
    'STORE_ID + "-" + WORKSTATION_NUMBER', 
    current_timestamp, current_timestamp);

The following example will synchronize to all nodes if the FLAG column has changed, otherwise no nodes will be synchronized. Note that here we make use of OLD_, which provides access to the old column value.


insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store-flag-changed','corp', 'store', 'bsh', 
    'FLAG != null && !FLAG.equals(OLD_FLAG)', 
    current_timestamp, current_timestamp);

The next example shows a script that iterates over each eligible node and checks to see if the trimmed value of the column named STATION equals the external_id.


insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store-trimmed-station','corp', 'store', 'bsh', 
    'for (org.jumpmind.symmetric.model.Node node : nodes) {
         if (STATION != null && node.getExternalId().equals(STATION.trim())) {
             targetNodes.add(node.getNodeId());
         }
      }', 
    current_timestamp, current_timestamp);

4.6.2.6. Audit Table Router

This router audits captured data by recording the change in an audit table that the router creates and keeps up to date (as long as auto.config.database is set to true.) The router creates a table named the same as the table for which data was captured with the suffix of _AUDIT. It will contain all of the same columns as the original table with the same data types only each column is nullable with no default values.

Three extra "AUDIT" columns are added to the table:

  • AUDIT_ID - the primary key of the table.
  • AUDIT_TIME - the time at which the change occurred.
  • AUDIT_EVENT - the DML type that happened to the row.

The following is an example of an audit router


insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    create_time, last_update_time)
values
  ('audit_at_corp','corp', 'local', 'audit', current_timestamp, current_timestamp);

Because the audit router isn't capturing data for a specific node in the system, but it still has to be associated with a node_group_link a new link action of type 'R' has been introduced. The 'R' stands for 'only routes to'

4.6.2.7. Utilizing External Select when Routing

There may be times when you wish to route based on a piece of data that exists in a table other than the one being routed. The approach, first discussed in Section 4.6.2.4, “Subselect Router”, is to utlize an external_select to save away data in external_data, which can then be referenced during routing.

Reconsider subselect's Order / OrderLineItem example (found in Section 4.6.2.4, “Subselect Router”), where routing for the line item is accomplished by linking to the "header" Order row. As an alternate way of solving the problem, we will now use External Select combined with a column match router.

In this version of the solution, the STORE_ID is captured from the Order table in the EXTERNAL_DATA column when the trigger fires. The router is configured to route based on the captured EXTERNAL_DATA to all nodes whose external id matches the captured external data.

insert into SYM_TRIGGER 
  (trigger_id,source_table_name,channel_id,external_select,
    last_update_time,create_time)
values
  ('orderlineitem', 'orderlineitem', 'orderlineitem','select STORE_ID 
    from order where order_id=$(curTriggerValue).$(curColumnPrefix)order_id',
    current_timestamp, current_timestamp);

insert into SYM_ROUTER 
  (router_id, source_node_group_id, target_node_group_id, router_type, 
    router_expression, create_time, last_update_time)
values
  ('corp-2-store-ext','corp', 'store', 'column', 
    'EXTERNAL_DATA=:EXTERNAL_ID', current_timestamp, current_timestamp);

Note the syntax $(curTriggerValue).$(curColumnPrefix). This translates into "OLD_" or "NEW_" based on the DML type being run. In the case of Insert or Update, it's NEW_. For Delete, it's OLD_ (since there is no new data). In this way, you can access the DML-appropriate value for your select statement.

The advantage of this approach over the 'subselect' approach is that it guards against the (somewhat unlikely) possibility that the master Order table row might have been deleted before routing has taken place. This external select solution also is a bit more efficient than the 'subselect' approach, although the triggers produced do run the extra external_select SQL inline with application database updates.

4.6.3. Trigger / Router Mappings

Two important controls can be configured for a specific Trigger / Router combination: Initial Loads and Ping Back. The parameters for these can be found in the Trigger / Router mapping table, TRIGGER_ROUTER.

4.6.3.1. Initial Loads

An initial load is the process of seeding tables at a target node with data from its parent node. When a node connects and data is extracted, after it is registered and if an initial load was requested, each table that is configured to synchronize to the target node group will be given a reload event in the order defined by the end user. A SQL statement is run against each table to get the data load that will be streamed to the target node. The selected data is filtered through the configured router for the table being loaded. If the data set is going to be large, then SQL criteria can optionally be provided to pair down the data that is selected out of the database.

An initial load can not occur until after a node is registered. An initial load is requested by setting the initial_load_enabled column on NODE_SECURITY to 1 on the row for the target node in the parent node's database. You can configure SymmetricDS to automatically perform an initial load when a node registers by setting the parameter auto.reload to true. Regardless of how the initial load is initiated, the next time the source node routes data, reload batches will be inserted. At the same time reload batches are inserted, all previously pending batches for the node are marked as successfully sent.

Important

Note that if the parent node that a node is registering with is not a registration server node (as can happen with a registration redirect or certain non-tree structure node configurations) the parent node's NODE_SECURITY entry must exist at the parent node and have a non-null value for column initial_load_time. Nodes can't be registered to non-registration-server nodes without this value being set one way or another (i.e., manually, or as a result of an initial load occuring at the parent node).

SymmetricDS recognizes that an initial load has completed when the initial_load_time column on the target node is set to a non-null value.

An initial load is accomplished by inserting reload batches in a defined order according to the initial_load_order column on TRIGGER_ROUTER. If the initial_load_order column contains a negative value the associated table will NOT be loaded. If the initial_load_order column contains the same value for multiple tables, SymmetricDS will attempt to order the tables according to foreign key constraints. If there are cyclical constraints, then foreign keys might need to be turned off or the initial load will need to be manually configured based on knowledge of how the data is structured.

Initial load data is always queried from the source database table. All data is passed through the configured router to filter out data that might not be targeted at a node.

Target table prep for initial load

There are several parameters that can be used to specify what, if anything, should be done to the table on the target database just prior to loading the data. Note that the parameters below specify the desired behavior for all tables in the initial load, not just one.

  • initial.load.delete.first / initial.load.delete.first.sql

    By default, an initial load will not delete existing rows from a target table before loading the data. If a delete is desired, the parameter initial.load.delete.first can be set to true. If true, the command found in initial.load.delete.first.sql will be run on each table prior to loading the data. Thd default value for initial.load.delete.first.sql is delete from %s, but could be changed if needed. Note that additional reload batches are created, in the correct order, to achieve the delete.

  • initial.load.create.first

    By default, an initial load will not create the table on the target if it doesn't aleady exist. If the desired behavior is to create the table on the target if it is not present, set the parameter intial.load.create.first to true. SymmetricDS will attempt to create the table and indexes on the target database before doing the initial load. (Additional batches are created to represent the table schema).

Loading subsets of data

An efficient way to select a subset of data from a table for an initial load is to provide an initial_load_select clause on TRIGGER_ROUTER. This clause, if present, is applied as a where clause to the SQL used to select the data to be loaded. The clause may use "t" as an alias for the table being loaded, if needed. The $(externalId) token can be used for subsetting the data in the where clause.

In cases where routing is done using a feature like Section 4.6.2.4, “Subselect Router”, an initial_load_select clause matching the subselect's criteria would be a more efficient approach. Some routers will check to see if the initial_load_select clause is provided, and they will not execute assuming that the more optimal path is using the initial_load_select statement.

One example of the use of an initial load select would be if you wished to only load data created more recently than the start of year 2011. Say, for example, the column created_time contains the creation date. Your initial_load_select would read created_time > ts {'2011-01-01 00:00:00.0000'} (using whatever timestamp format works for your database). This then gets applied as a where clause when selecting data from the table.

Important

When providing an initial_load_select be sure to test out the criteria against production data in a query browser. Do an explain plan to make sure you are properly using indexes.

Reverse Initial Loads

The default behavior for initial loads is to load data from the registration server or parent node, to a client node. Occasionally, there may be need to do a one-time intial load of data in the opposite or "reverse" direction, namely from a client node to the registration node. To achieve this, set the parameter auto.reload.reverse to be true, but only for the specific node group representing the client nodes. This will cause a one time reverse load of data, for tables configured with non-negative initial load orders, to be batched at the point when registration of the client node is occurring. These batches are then sent to the parent or registration node. This capability might be needed, for example, if there is data already present in the client that doesn't exist in the parent but needs to.

4.6.3.2. Dead Triggers

Occasionally the decision of what data to load initially results in additional triggers. These triggers, known as Dead Triggers, are configured such that they do not capture any data changes. A "dead" Trigger is one that does not capture data changes. In other words, the sync_on_insert, sync_on_update, and sync_on_delete properties for the Trigger are all set to false. However, since the Trigger is specified, it will be included in the initial load of data for target Nodes.

Why might you need a Dead Trigger? A dead Trigger might be used to load a read-only lookup table, for example. It could also be used to load a table that needs populated with example or default data. Another use is a recovery load of data for tables that have a single direction of synchronization. For example, a retail store records sales transaction that synchronize in one direction by trickling back to the central office. If the retail store needs to recover all the sales transactions from the central office, they can be sent are part of an initial load from the central office by setting up dead Triggers that "sync" in that direction.

The following SQL statement sets up a non-syncing dead Trigger that sends the sale_transaction table to the "store" Node Group from the "corp" Node Group during an initial load.


insert into sym_trigger (TRIGGER_ID,SOURCE_CATALOG_NAME,
  SOURCE_SCHEMA_NAME,SOURCE_TABLE_NAME,CHANNEL_ID,
  SYNC_ON_UPDATE,SYNC_ON_INSERT,SYNC_ON_DELETE,
  SYNC_ON_INCOMING_BATCH,NAME_FOR_UPDATE_TRIGGER,
  NAME_FOR_INSERT_TRIGGER,NAME_FOR_DELETE_TRIGGER,
  SYNC_ON_UPDATE_CONDITION,SYNC_ON_INSERT_CONDITION,
  SYNC_ON_DELETE_CONDITION,EXTERNAL_SELECT,
  TX_ID_EXPRESSION,EXCLUDED_COLUMN_NAMES,
  CREATE_TIME,LAST_UPDATE_BY,LAST_UPDATE_TIME) 
  values ('SALE_TRANSACTION_DEAD',null,null,
  'SALE_TRANSACTION','transaction',
  0,0,0,0,null,null,null,null,null,null,null,null,null,
  current_timestamp,'demo',current_timestamp);

insert into sym_router (ROUTER_ID,TARGET_CATALOG_NAME,TARGET_SCHEMA_NAME,
  TARGET_TABLE_NAME,SOURCE_NODE_GROUP_ID,TARGET_NODE_GROUP_ID,ROUTER_TYPE,
  ROUTER_EXPRESSION,SYNC_ON_UPDATE,SYNC_ON_INSERT,SYNC_ON_DELETE,
  CREATE_TIME,LAST_UPDATE_BY,LAST_UPDATE_TIME) 
  values ('CORP_2_STORE',null,null,null,
  'corp','store',null,null,1,1,1,
  current_timestamp,'demo',current_timestamp);
   
insert into sym_trigger_router (TRIGGER_ID,ROUTER_ID,INITIAL_LOAD_ORDER,
  INITIAL_LOAD_SELECT,CREATE_TIME,LAST_UPDATE_BY,LAST_UPDATE_TIME) 
  values ('SALE_TRANSACTION_DEAD','CORP_2_REGION',100,null,
   current_timestamp,'demo',current_timestamp);
   

4.6.3.3. Enabling "Ping Back"

As discussed in Section 3.6.3.2, “Circular References and "Ping Back"” SymmetricDS, by default, avoids circular data changes. When a trigger fires as a result of SymmetricDS itself (such as the case when sync on incoming batch is set), it records the originating source node of the data change in source_node_id. During routing, if routing results in sending the data back to the originating source node, the data is not routed by default. If instead you wish to route the data back to the originating node, you can set the ping_back_enabled column for the needed particular trigger / router combination. This will cause the router to "ping" the data back to the originating node when it usually would not.

4.7. Opening Registration

Node registration is the act of setting up a new NODE and NODE_SECURITY so that when the new node is brought online it is allowed to join the system. Nodes are only allowed to register if rows exist for the node and the registration_enabled flag is set to 1. If the auto.registration SymmetricDS property is set to true, then when a node attempts to register, if registration has not already occurred, the node will automatically be registered.

SymmetricDS allows you to have multiple nodes with the same external_id. Out of the box, openRegistration will open a new registration if a registration already exists for a node with the same external_id. A new registration means a new node with a new node_id and the same external_id will be created. If you want to re-register the same node you can use the reOpenRegistration() JMX method which takes a node_id as an argument.

4.8. Transforming Data

New as of SymmetricDS 2.4, SymmetricDS is now able to transform synchronized data by way of configuration (previously, for most cases a custom data loader would need to have been written). This transformation can take place on a source node or on a target node, as the data is being loaded or extracted. With this new feature you can, for example:

  • Copy a column from a source table to two (or more) target table columns,

  • Merge columns from two or more source tables into a single row in a target table,

  • Insert constants in columns in target tables based on source data synchronizations,

  • Insert multiple rows of data into a single target table based on one change in a source table,

  • Apply a Bean Shell script to achieve a custom transform when loading into the target database.

These transformations can take place either on the target or on the source, and as data is either being extracted or loaded. In either case, the transformation is initiated due to existence of a source synchronization trigger. The source trigger creates the synchronization data, while the transformation configuration decides what to do with the sychronization data as it is either being extracted from the source or loaded into the target. You have the flexibility of defining different transformation behavior depending on whether the source change that triggered the synchronization was an Insert, Update, or Delete. In the case of Delete, you even have options on what exactly to do on the target side, be it a delete of a row, setting columns to specific values, or absolutely nothing at all.

A few key concepts are important to keep in mind to understand how SymmetricDS performs transformations. The first concept is that of the "source operation" or "source DML type", which is the type of operation that occurred to generate the synchronization data in the first place (i.e., an insert, a delete, or an update). Your transformations can be configured to act differently based on the source DML type, if desired. When transforming, by default the DML action taken on the target matches that of the action taken on the row in the source (although this behavior can be altered through configuration if needed). If the source DML type is an Insert, for example, the resulting transformation DML(s) will be Insert(s).

Another important concept is the way in which transforms are applied. Each source operation may map to one or more transforms and result in one or more operations on the target tables. Each of these target operations are performed as independent operations in sequence and must be "complete" from a SQL perspective. In other words, you must define columns for the transformation that are sufficient to fill in any primary key or other required data in the target table if the source operation was an Insert, for example.

Finally, please note that the tranformation engine relies on a source trigger / router existing to supply the source data for the transformation. The transform configuration will never be used if the source table and target node group does not have a defined trigger / router combination for that source table and target node group.

4.8.1. Transform Configuration Tables

SymmetricDS stores its transformation configuration in two configuration tables, TRANSFORM_TABLE and TRANSFORM_COLUMN. Defining a transformation involves configuration in both tables, with the first table defining which source and destination tables are involved, and the second defining the columns involved in the transformation and the behavior of the data for those columns. We will explain the various options available in both tables and the various pre-defined transformation types.

To define a transformation, you will first define the source table and target table that applies to a particular transformation. The source and target tables, along with a unique identifier (the transform_id column) are defined in TRANSFORM_TABLE. In addition, you will specify the source_node_group_id and target_node_group_id to which the transform will apply, along with whether the transform should occur on the Extract step or the Load step (transform_point). All of these values are required.

Three additional configuration settings are also defined at the source-target table level: the order of the transformations, the behavior when deleting, and whether an update should always be attempted first. More specifically,

  • transform_order: For a single source operation that is mapped to a transformation, there could be more than one target operation that takes place. You may control the order in which the target operations are applied through a configuration parameter defined for each source-target table combination. This might be important, for example, if the foreign key relationships on the target tables require you to execute the transformations in a particular order.
  • column_policy: Indicates whether unspecified columns are passed thru or if all columns must be explicitly defined. The options include:
    • SPECIFIED - Indicates that only the transform columns that are defined will be the ones that end up as part of the transformation.
    • IMPLIED - Indicates that if not specified, then columns from the source are passed through to the target. This is useful if you just want to map a table from one name to anther or from one schema to another. It is also useful if you want to transform a table, but also want to pass it through. You would define and implied transform from the source to the target and would not have to configure each column.
  • delete_action: When a source operation of Delete takes place, there are three possible ways to handle the transformation at the target. The options include:
    • NONE - The delete results in no target changes.
    • DEL_ROW - The delete results in a delete of the row as specified by the pk columns defined in the transformation configuration.
    • UPDATE_COL - The delete results in an Update operation on the target which updates the specific rows and columns based on the defined transformation.
  • update_first: This option overrides the default behavior for an Insert operation. Instead of attempting the Insert first, SymmetricDS will always perform an Update first and then fall back to an Insert if that fails. Note that, by default, fall back logic always applies for Insert and Updates. Here, all you a specifying is whether to always do an Update first, which can have performance benefits under certain situations you may run into.

For each transformation defined in TRANSFORM_TABLE, the columns to be transformed (and how they are transformed) are defined in TRANSFORM_COLUMN. This column-level table typically has several rows for each transformation id, each of which defines the source column name, the target column name, as well as the following details:

  • include_on: Defines whether this entry applies to source operations of Insert (I), Update (U), or Delete (D), or any source operation.
  • pk: Indicates that this mapping is used to define the "primary key" for identifying the target row(s) (which may or may not be the true primary key of the target table). This is used to define the "where" clause when an Update or Delete on the target is occurring. At least one row marked as a pk should be present for each transform_id.
  • transform_type, transform_expression: Specifies how the data is modified, if at all. The available transform types are discussed below, and the default is 'copy', which just copies the data from source to target.
  • transform_order: In the event there are more than one columns to transform, this defines the relative order in which the transformations are applied.

4.8.2. Transformation Types

There are several pre-defined transform types available in SymmetricDS. Additional ones can be defined by creating and configuring an extension point which implements the IColumnTransform interface. The pre-defined transform types include the following (the transform_type entry is shown in parentheses):

  • Copy Column Transform ('copy'): This transformation type copies the source column value to the target column. This is the default behavior.
  • Constant Transform ('const'): This transformation type allows you to map a constant value to the given target column. The constant itself is placed in transform_expression.
  • Variable Transform ('variable'): This transformation type allows you to map a built-in dynamic variable to the given target column. The variable name is placed in transform_expression. The following variables are available: Ssystem_date is the current system date, system_timestamp is the current system date and time, source_node_id is the node id of the source, target_node_id is the node id of the target, and null is a null value.
  • Additive Transform ('additive'): This transformation type is used for numeric data. It computes the change between the old and new values on the source and then adds the change to the existing value in the target column. That is, target = target + multiplier (source_new - source_old), where multiplier is a constant found in the transform_expression (default is 1 if not specified). For example, if the source column changed from a 2 to a 4, the target column is currently 10, and the multiplier is 3, the effect of the transform will be to change the target column to a value of 16 ( 10+3*(4-2) => 16 ). Note that, in the case of deletes, the new column value is considered 0 for the purposes of the calculation.
  • Substring Transform ('substr'): This transformation computes a substring of the source column data and uses the substring as the target column value. The transform_expression can be a single integer (n, the beginning index), or a pair of comma-separated integers (n,m - the beginning and ending index). The transform behaves as the Java substring function would using the specified values in transform_expression.
  • Multiplier Transform ('multiply'): This transformation allows for the creation of multiple rows in the target table based on the transform_expression. This transform type can only be used on a primary key column. The transform_expression is a SQL statement that returns the list to be used to create the multiple targets.
  • Lookup Transform ('lookup'): This transformation determines the target column value by using a query, contained in transform_expression to lookup the value in another table. The query must return a single row, and the first column of the query is used as the value. Your query references source column names by prefixing with a colon (e.g., :MY_COLUMN).
  • Shell Script Transform ('bsh'): This transformation allows you to provide a Bean Shell script in transform_expression and executes the script at the time of transformation. Some variables are provided to the script: COLUMN_NAME is a variable for a source column in the row, where the variable name is the column name in uppercase; currentValue is the value of the current source column; oldValue is the old value of the source column for an updated row; sqlTemplate is a org.jumpmind.db.sql.ISqlTemplate object for querying or updating the database; channelId is a reference to the channel on which the transformation is happening; sourceNode is a org.jumpmind.symmetric.model.Node object that represents the node from where the data came; targetNode is a org.jumpmind.symmetric.model.Node object that represents the node where the data is being loaded.
  • Identity Transform ('identity'): This transformation allows you to insert into an identity column by computing a new identity, not copying the actual identity value from the source.

4.9. Data Load Filters

New as of SymmetricDS 3.1, SymmetricDS is now capable of taking actions upon the load of certain data via configurable load filters. This new configurable option is in additon to the already existing option of writing a class that implements IDatabaseWriterFilter. A configurable load filter watches for specific data that is being loaded and then takes action based on the load of that data.

Specifying which data to action is done by specifying a souce and target node group (data extracted from this node group, and loaded into that node group), and a target catalog, schema and table name. You can decide to take action on rows that are inserted, updated and/or deleted, and can also further delineate which rows of the target table to take action on by specifying additional criteria in the bean shell script that is executed in response to the loaded data. As an example, old and new values for the row of data being loaded are available in the bean shell script, so you can action rows with a certain column value in old or new data.

The action taken is based on a bean shell script that you can provide as part of the configuration. Actions can be taken at different points in the load process including before write, after write, at batch complete, at batch commit and/or at batch rollback.

4.9.1. Load Filter Configuration Table

SymmetricDS stores its load filter configuration in a single table called LOAD_FILTER. The load filter table allows you to specify the following:

  • Load Filter Type ('load_filter_type'): The type of load filter. Today only beanshell is support ('BSH'), but SQL scripts may be added in a future release.
  • Source Node Group ('source_node_group_id'): The source node group for which you would like to watch for changes.
  • Target Node Group ('target_node_group_id'): The target node group for which you would like to watch for changes. The source and target not groups are used together to identify the node group link for which you would like to watch for changes (i.e. When the Server node group sends data to a Client node group).
  • Target Catalog ('target_catalog_name'): The name of the target catalog for which you would like to watch for changes.
  • Target Schema ('target_schema_name'): The name of the target schema for which you would like to watch for changes.
  • Target Table ('target_table_name'): The name of the target table for which you would like to watch for changes. The target catalog, target schema and target table name are used together to fully qualify the table for which you would like to watch for changes.
  • Filter on Update ('filter_on_update'): Determines whether the load filter takes action (executes) on a database update statement.
  • Filter on Insert ('filter_on_insert'): Determines whether the load filter takes action (executes) on a database insert statement.
  • Filter on Delete ('filter_on_delete'): Determines whether the load filter takes action (executes) on a database delete statement.
  • Before Write Script ('before_write_script'): The script to execute before the database write occurs.
  • After Write Script ('after_write_script'): The script to execute after the database write occurs.
  • Batch Complete Script ('batch_complete_script'): The script to execute after the entire batch completes.
  • Batch Commit Script ('batch_commit_script'): The script to execute after the entire batch is committed.
  • Batch Rollback Script ('batch_rollback_script'): The script to execute if the batch rolls back.
  • Handle Error Script ('handle_error_script'): A script to execute if data cannot be processed.
  • Load Filter Order ('load_filter_order'): The order in which load filters should execute if there are multiple scripts pertaining to the same source and target data.

4.9.2. Variables available to Data Load Filters

As part of the bean shell load filters, SymmetricDS provides certain variables for use in the bean shell script. Those variables include:

  • Symmetric Engine ('ENGINE'): The Symmetric engine object.
  • Source Values ('<COLUMN_NAME>'): The source values for the row being inserted, updated or deleted.
  • Old Values ('OLD_<COLUMN_NAME>'): The old values for the row being inserted, updated or deleted.
  • Data Context ('CONTEXT'): The data context object for the data being inserted, updated or deleted. .
  • Table Data ('TABLE'): The table object for the table being inserted, updated or deleted.

4.9.3. Data Load Filter Example

The following is an example of a load filter that watches a table named TABLE_TO_WATCH being loaded from the Server Node Group to the Client Node Group for inserts or updates, and performs an initial load on a table named "TABLE_TO_RELOAD" for KEY_FIELD on the reload table equal to a column named KEY_FIELD on the TABLE_TO_WATCH table.

insert into sym_load_filter 
   (LOAD_FILTER_ID, LOAD_FILTER_TYPE, SOURCE_NODE_GROUP_ID, TARGET_NODE_GROUP_ID,
    TARGET_CATALOG_NAME, TARGET_SCHEMA_NAME, TARGET_TABLE_NAME, 
    FILTER_ON_UPDATE, FILTER_ON_INSERT, FILTER_ON_DELETE, 
    BEFORE_WRITE_SCRIPT, AFTER_WRITE_SCRIPT, BATCH_COMPLETE_SCRIPT, 
    BATCH_COMMIT_SCRIPT, BATCH_ROLLBACK_SCRIPT, HANDLE_ERROR_SCRIPT, 
    CREATE_TIME, LAST_UPDATE_BY, LAST_UPDATE_TIME,
    LOAD_FILTER_ORDER, FAIL_ON_ERROR)
values ('TABLE_TO_RELOAD','BSH','Client','Server',NULL,NULL,
    'TABLE_TO_WATCH',1,1,0,null,
    'engine.getDataService().reloadTable(context.getBatch().getSourceNodeId(), 
    table.getCatalog(), table.getSchema(),
    "TABLE_TO_RELOAD","KEY_FIELD=''" + KEY_FIELD + "''");'
    ,null,null,null,null,sysdate,'userid',sysdate,1,1);

4.10. Conflict Detection and Resolution

Conflict detection and resolution is new as of SymmetricDS 3.0. Conflict detection is the act of determining if an insert, update or delete is in "conflict" due to the target data row not being consistent with the data at the source prior to the insert/update/delete. Conflict resolution is the act of figuring out what to do when a conflict is detected.

Conflict detection and resolution strategies are configured in the CONFLICT table. They are configured at minimum for a specific NODE_GROUP_LINK . The configuration can also be specific to a CHANNEL and/or table.

Conflict detection is configured in the detect_type and detect_expression columns of CONFLICT . The value for detect_expression depends on the detect_type . Conflicts are detected while data is being loaded into a target system.

USE_PK_DATA

Indicates that only the primary key is used to detect a conflict. If a row exists with the same primary key, then no conflict is detected during an update or a delete. Updates and deletes rows are resolved using only the primary key columns. If a row already exists during an insert then a conflict has been detected.

USE_OLD_DATA

Indicates that all of the old data values are used to detect a conflict. Old data is the data values of the row on the source system prior to the change. If a row exists with the same old values on the target system as they were on the source system, then no conflict is detected during an update or a delete. If a row already exists during an insert then a conflict has been detected.

Note that some platforms do not support comparisons of binary columns. Conflicts in binary column values will not be detected on the following platforms: DB2, DERBY, ORACLE, and SQLSERVER.

USE_CHANGED_DATA

Indicates that the primary key plus any data that has changed on the source system will be used to detect a conflict. If a row exists with the same old values on the target system as they were on the source system for the columns that have changed on the source system, then no conflict is detected during an update or a delete. If a row already exists during an insert then a conflict has been detected.

Note that some platforms do not support comparisons of binary columns. Conflicts in binary column values will not be detected on the following platforms: DB2, DERBY, ORACLE, and SQLSERVER.

USE_TIMESTAMP

Indicates that the primary key plus a timestamp column (as configured in detect_expression ) will indicate whether a conflict has occurred. If the target timestamp column is not equal to the old source timestamp column, then a conflict has been detected. If a row already exists during an insert then a conflict has been detected.

USE_VERSION

Indicates that the primary key plus a version column (as configured in detect_expression ) will indicate whether a conflict has occurred. If the target version column is not equal to the old source version column, then a conflict has been detected. If a row already exists during an insert then a conflict has been detected.

The choice of how to resolve a detected conflict is configured via the resolve_type column. Depending on the setting, two additional boolean settings may also be configured, namely resolve_row_only and resolve_changes_only, as discussed in the resolution settings below.

FALLBACK

Indicates that when a conflict is detected the system should automatically apply the changes anyways. If the source operation was an insert, then an update will be attempted. If the source operation was an update and the row does not exist, then an insert will be attempted. If the source operation was a delete and the row does not exist, then the delete will be ignored. The resolve_changes_only flag controls whether all columns will be updated or only columns that have changed will be updated during a fallback operation.

IGNORE

Indicates that when a conflict is detected the system should automatically ignore the incoming change. The resolve_row_only column controls whether the entire batch should be ignore or just the row in conflict.

MANUAL

Indicates that when a conflict is detected the batch will remain in error until manual intervention occurs. The row in error is inserted into the INCOMING_ERROR table. In order to resolve, the resolve_data column can be manually filled out which will be used on the next load attempt instead of the original source data. The resolve_ignore flag can also be used to indicate that the row should be ignored on the next load attempt.

NEWER_WINS

Indicates that when a conflict is detected by USE_TIMESTAMP or USE_VERSION that the either the source or the target will win based on the which side has the newer timestamp or higher version number.

For each configured conflict, you also have the ability to control if and how much "resolved" data is sent back to the node who's data change is in conflict. This "ping back" behavior is specified by the setting of the ping_back column and can be one of the following values:

OFF

No data is sent back to the originating node, even if the resolved data doesn't match the data the node sent.

SINGLE_ROW

The resolved data of the single row in the batch that caused the conflict is sent back to the originating node.

REMAINING_ROWS.

The resolved data of the single row in the batch in conflict, along with the entire remainder of the batch, is sent back to the originating node.