ODI doc

Creating an Excel Data Server

Posted on July 6, 2011

P R E P A R E Y O U R E X C E L S P R E A D S H E E T

First open up a Microsoft Excel spreadsheet, we will need to define a named range.

Step: 1)

Open spreadsheet

Step: 3) Select the range for the data

D E FI N E A N O D B C D A T A S O U R C E

Step: 2) click on Add select the Excel Driver press „Finish‟. Specify the data source Name and

Step: 3) Specify the Excel file path Press ok. You should now see your new ODBC Data Source

C R E A T E A D A T A S E R V E R I N T O PO L O G Y M A N A G E R

Step: 1)

Open up Topology Manager and go to Physical Architecture. Right click on theMicrosoft Excel technology and select New Data Server. In the Data Server window enter a name in the Name field.

Step: 2) Go to the JDBC tab. Select the Sun JDBC-ODBC Bridge in the JDBC DriverList.

Step: 3) In the JDBC URL template replace with the name of the ODBC Data Source you

specified earlier. I used Excel data Server in this example.

Click OK.

Step: 5) Go to Newly created data server and Right click select New Physical Schema

Create New Logical Schema:

Step: 1)

Select Microsoft Excel in Logical Architecture tab Right click and select new logical schema. Specify the name and map it with Contexts.

Create Model for Excel

Step: 1)

Go to the Designer Navigator select model tab and create new model for excel.

Step: 2) Specify the Name, Technology and Logical schema.

Step: 3) Select Reverse Engineering Tab. Select system table check box and go to Selective

reverse Engineering tab.

Step: 4) Here select Selective reverse Engineering and Objects to reverse Engineering check

Step: 5) Save it and perform reverse Engineer of this model.

Done !

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Creating an XML Data Server

Posted on July 6, 2011

An XML Data Server corresponds to one XML file that is accessible through your local network.

XML files are accessed through the Oracle Data Integrator Driver for XML. This JDBC driver loads the XML file hierarchical structure in a relational structure in a schema stored in memory to enable SQL queries through JDBC. It is also able to unload the relational structure back in the XML File.

You must have following information:

· The location of the DTD file associated with your XML file

· The location of the XML file

· The name of the Root element of your XML file

Creation of the Data Server

Step: 2) Fill in the following fields in the Definition tab:

· Name: Name of the Data Server as it will appear in Oracle Data Integrator.

· User/Password: Not used here.

Step: 3) Fill in the following fields in the JDBC tab:

JDBC Driver: com.sunopsis.jdbc.driver.xml.SnpsXmlDriver

JDBC URL: jdbc:snps:xml?[property=value&property=value...]

JDBC Driver Properties:

Example:

jdbc:snps:xml?f=../xml/department.xml&re=Department_DIM&ro=false&case_sens=true&s=Depart

Step: 4) Click test Connection button it will ask you for saving it press „ok‟ then it will ask again for creating physical schema press „ok‟

Creating a Physical Schema for XML

The Physical Schema will be a storage location for the tables associated with the XML file.

Step: 2)

Name the Schema and Work Schema. Note that if you have named the schemawith the s= property of the JDBC URL of the XML Data Server, you must use the same schema name here.

Step: 3) Save it.

A Logical Schema can be associated with only one Physical Schema in a given Context.

Creating Model for XML:

Step: 1) Select Model tab in designer Navigator and select New model.

Step: 2) In Definition Tab Specify the following details.

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Introduction to Knowledge Modules

Posted on June 5, 2011

1) What is a Knowledge Module?

Knowledge Modules (KMs) are code templates. Each KM is dedicated to an individual task in the overall data integration process. The code in the KMs appears in nearly the form that it will be executed except that it includes Oracle Data Integrator (ODI) substitution methods enabling it to be used generically by many different integration jobs. The code that is generated and executed is derived from the declarative rules and metadata defined in the ODI Designer module.

2)

Types of Knowledge Modules:

2.1) Reverse-Engineering Knowledge Modules (RKM)

The RKM role is to perform customized reverse engineering for a model. The RKM is in charge

of connecting to the application or meta-data provider then transforming and writing the

resulting meta-data into Oracle Data Integration‟s repository. The meta-data is written

temporarily into the

SNP_REV_xx

tables. The RKM then calls the Oracle Data Integrator API to

read from these tables and write to Oracle Data Integrators meta-data tables of the work

repository in incremental update mode. This is illustrated below

A typical RKM follows these steps:

a).Cleans up the SNP_REV_xx tables from previous executions using the OdiReverseResetTable tool.

b). Retrieves sub models, datastores, columns, unique keys, foreign keys, conditions from the metadata provider to SNP_REV_SUB_MODEL, SNP_REV_TABLE,SNP_REV_COL, SNP_REV_KEY,SNP_REV_KEY_COL, SNP_REV_JOIN, SNP_REV_JOIN_COL, SNP_REV_COND tables.

C). Updates the model in the work repository by calling the OdiReverseSetMetaData tool.

Available RKM in ODI 11.1.1

1) RKM DB2/400

2) RKM FILE (FROM EXCEL)

3) RKM HYPERION ESSBASE 4) RKM FINANCIAL MANAGEMENT 5) RKM HYPERION PLANNING 6) RKM INFORMIX 7) RKM INFORMIX SE 8) RKM MSSQL 9) RKM ORACLE 10) RKM ORACLE (JYOTHON)

11) RKM ORACLE DATA QUALITY

12) RKM ORACLE OLAP (JYOTHON)

13) RKM SQL (JYOTHON)

14) RKM TERADATA

The CKM accepts a set of constraints and the name of the table to check. It creates an “E$” error table which it writes all the rejected records to. The CKM can also remove the erroneous records from the checked result set.

The following figures show how a CKM operates in both STATIC_CONTROL and FLOW_CONTROL modes.

2.2) Check Knowledge Modules (CKM)

The CKM is in charge of checking that records of a data set are consistent with defined constraints. The CKM is used to maintain data integrity and participates in the overall data quality initiative. The CKM can be used in 2 ways:

a) To check the consistency of existing data. This can be done on any datastore or within interfaces, by setting the STATIC_CONTROL option to “Yes”. In the first case, the data checked is the data currently in the datastore. In the second case, data in the target datastore is checked after it is loaded.

b) To check consistency of the incoming data before loading the records to a target datastore. This is done by using the FLOW_CONTROL option. In this case, the CKM simulates the constraints of the target datastore on the resulting flow prior to writing to the target

(STATIC_CONTROL)

In STATIC_CONTROL mode, the CKM reads the constraints of the table and checks them

against the data of the table. Records that don‟t match the constraints are written to the “E$”

error table in the staging area.

(FLOW_CONTROL)

In FLOW_CONTROL mode, the CKM reads the constraints of the target table of the Interface. It checks these constraints against the data contained in the “I$” flow table of the staging area. Records that violate these constraints are written to the “E$” table of the staging area. In both cases, a CKM usually performs the following tasks:

a) Create the “E$” error table on the staging area. The error table should contain the same columns as the datastore as well as additional columns to trace error messages, check origin, check date etc. b) Isolate the erroneous records in the “E$” table for each primary key, alternate key, foreign key, condition,

mandatory column that needs to be checked.

c) If required, remove erroneous records from the table that has been checked

Available CKM in ODI 11.1.1 a) CKM HSQL b) CKM NETEZZA c) CKM ORACLE d) CKM SQL e) CKM SYBASE IQ

f) CKM TERADATA

2.3) Loading Knowledge Modules (LKM)

An LKM is in charge of loading source data from a remote server to the staging area. It is used by interfaces when some of the source datastores are not on the same data server as the staging area. The LKM implements the declarative rules that need to be executed on the source server and retrieves a single result set that it stores in a “C$” table in the staging area, as illustrated below.

The LKM creates the “C$” temporary table in the staging area. This table will

hold records loaded from the source server

a) The LKM obtains a set of pre-transformed records from the source server by executing the appropriate transformations on the source. Usually, this is done by a single SQL SELECT query when the source server is an RDBMS. When the source doesn‟t have SQL capacities (such as flat files or applications), the LKM simply reads the source data with the appropriate method (read file or execute API).

b) The LKM loads the records into the “C$” table of the staging area.

An interface may require several LKMs when it uses datastores from different sources. When all source datastores are on the same data

server as the staging area, no LKM is required.

Available LKM in ODI 11.1.1

1) LKM ATUNITY TO SQL

2) LKM DB2 400 JOURNAL TO SQL 3) LKM DB2 400 JOURNAL TO DB2 400 4) LKM DB2 UDB to DB2 UDB (EXPORT_IMPORT) 5) LKM File to DB2 UDB (LOAD) 6) LKM File to MSSQL (BULK) 7) LKM File to Netezza (EXTERNAL TABLE) 8) LKM File to Netezza (NZLOAD) 9) LKM File to Oracle (EXTERNAL TABLE) 10) LKM File to Oracle (SQLLDR)

11) LKM File to SQL

12) LKM File to Sybase IQ (LOAD TABLE) 13) LKM File to Teradata (TTU) 14) LKM Hyperion Essbase DATA to SQL 15) LKM Hyperion Essbase METADATA to SQL 16) LKM Hyperion Financial Management Data to SQL 17) LKM Hyperion Financial Management Members To SQL 18) LKM Informix to Informix (SAME SERVER)

20) LKM JMS XML to SQL 21) LKM MSSQL to MSSQL (BCP) 22) LKM MSSQL to MSSQL (LINKED SERVERS) 23) LKM MSSQL to ORACLE (BCP SQLLDR) 24) LKM MSSQL to SQL (ESB XREF) 25) LKM Oracle BI to Oracle (DBLINK)

26) LKM Oracle BI to SQL

27) LKM Oracle to Oracle (data pump) 28) LKM Oracle to Oracle (DBLINK) 29) LKM SQL to DB2 400 (CPYFRMIMPF) 30) LKM SQL to DB2 UDB 31) LKM SQL to DB2 UDB (LOAD) 32) LKM SQL to MSSQL 33) LKM SQL to MSSQL (BULK) 34) LKM SQL to Oracle 35) LKM SQL to SQL 36) LKM SQL to SQL (ESB XREF) 37) LKM SQL to SQL (JYTHON) 38) LKM SQL to SQL (row by row) 39) LKM SQL to Sybase ASE 40) LKM SQL to Sybase ASE (BCP) 41) LKM SQL to Sybase IQ (LOAD TABLE) 42) LKM SQL to Teradata (TTU) 43) LKM Sybase ASE to Sybase ASE (BCP)

2.4) Integration Knowledge Modules (IKM)

The IKM is in charge of writing the final, transformed data to the target table. Every interface uses a single IKM. When the IKM is started, it assumes that all loading phases for the remote servers have already carried out their tasks. This means that all remote source data sets have been loaded by LKMs into “C$” temporary tables in the staging area, or the source datastores are on the same data server as the staging area.

Therefore, the IKM simply needs to execute the “Staging and Target” transformations, joins and filters on the “C$” tables, and tables located on the same data server as the staging area. The resulting set is usually processed by the IKM and written into the “I$” temporary table before loading it to the target. These final transformed records can be written in several ways depending on the IKM selected in your interface. They may be simply appended to the target, or compared for incremental updates or for slowly changing dimensions. There are 2 types of IKMs: those that assume that the staging area is on the same server as the target datastore, and those that can be used when it is not. These are illustrated below:

(Staging Area on Target)

When the staging area is on the target server, the IKM usually follows these steps:

a) The IKM executes a single set-oriented SELECT statement to carry out staging area and target declarative rules on all “C$” tables and local tables (such as D in the figure). This generates a result set.

b) Simple “append” IKMs directly write this result set into the target table. More complex IKMs create an “I$” table to store this result set.

c) If the data flow needs to be checked against target constraints, the IKM calls a CKM to isolate erroneous records and cleanse the “I$” table.

d) The IKM writes records from the “I$” table to the target following the defined strategy (incremental update, slowly changing dimension, etc.).

e) The IKM drops the “I$” temporary table.

f) Optionally, the IKM can call the CKM again to check the consistency of the target datastore.

These types of KMs do not manipulate data outside of the target server. Data processing is set-oriented for maximum efficiency when performing jobs on large volumes.

(Staging Area Different from Target)

When the staging area is different from the target server, as shown in Figure, the IKM usually follows these steps: a) The IKM executes a single set-oriented SELECT statement to carry out declarative rules on all “C$” tables and tables located on the staging area (such as D in the figure). This generates a result set.

b) The IKM loads this result set into the target datastore, following the defined strategy (append or incremental update).

This architecture has certain limitations, such as:

A CKM cannot be used to perform a data integrity audit on the data being processed.

Data needs to be extracted from the staging area before being loaded to the target, which may lead to performance issues.

Available IKM in ODI 11.1.1

2)

IKM DB2 400 Incremental Update

3)

IKM DB2 400 Incremental Update (CPYF)

4)

IKM DB2 400 Slowly Changing Dimension

5)

IKM DB2 UDB Incremental Update

6)

IKM DB2 UDB Slowly Changing Dimension

7)

IKM File to Teradata (TTU)

8)

IKM Informix Incremental Update

9)

IKM MSSQL Incremental Update

10)

IKM MSSQL Slowly Changing Dimension

11)

IKM Netezza Control Append

12)

IKM Netezza Incremental Update

13)

IKM Netezza To File (EXTERNAL TABLE)

14)

IKM Oracle AW Incremental Update

15)

IKM Oracle BI to SQL Append

16)

IKM Oracle Incremental Update

17)

IKM Oracle Incremental Update (MERGE)

18)

IKM Oracle Incremental Update (PL SQL)

19)

IKM Oracle Multi Table Insert

20)

IKM Oracle Slowly Changing Dimension

21)

IKM Oracle Spatial Incremental Update

22)

IKM SQL Control Append

23)

IKM SQL Control Append (ESB XREF)

24)

IKM SQL Incremental Update

25)

IKM SQL Incremental Update (row by row)

26)

IKM SQL to File Append

27)

IKM SQL to Hyperion Essbase (DATA)

28)

IKM SQL to Hyperion Essbase (METADATA)

29)

IKM SQL to Hyperion Financial Management Data

30)

IKM SQL to Hyperion Financial Management Dimension

31)

IKM SQL to Hyperion Planning

32)

IKM SQL to JMS Append

33)

IKM SQL to JMS XML Append

34)

IKM SQL to SQL Append

35)

IKM SQL to Teradata (TTU)

36)

IKM Sybase ASE Incremental Update

37)

IKM Sybase ASE Slowly Changing Dimension

38)

IKM Sybase IQ Incremental Update

39)

IKM Sybase IQ Slowly Changing Dimension

40)

IKM Teradata Control Append

41)

IKM Teradata Incremental Update

42)

IKM Teradata Multi Statement

43)

IKM Teradata Slowly Changing Dimension

44)

IKM Teradata to File (TTU)

45)

IKM XML Control Append

JKMs create the infrastructure for Change Data Capture on a model, a sub model or a datastore.

JKMs are not used in interfaces, but rather within a model to define how the CDC infrastructure

is initialized. This infrastructure is composed of a subscribers table, a table of changes, views on

this table and one or more triggers or log capture programs as illustrated below.

Available JKM in ODI 11.1.1 1) JKM DB2 400 Consistent 2) JKM DB2 400 Simple 3) JKM DB2 400 Simple (Journal) 4) JKM DB2 UDB Consistent 5) JKM DB2 UDB Simple 6) JKM HSQL Consistent 7) JKM HSQL Simple 8) JKM Informix Consistent 9) JKM Informix Simple 10) JKM MSSQL Consistent 11) JKM MSSQL Simple

12) JKM Oracle 10g Consistent (Streams)

13) JKM Oracle 11g Consistent (Streams)

14) JKM Oracle Consistent

15) JKM Oracle Consistent (Update Date)

16) JKM Oracle Simple

17) JKM Oracle to Oracle Consistent (OGG)

18) JKM Sybase ASE Consistent

19) JKM Sybase ASE Simple

2.6) Service Knowledge Modules (SKM)

SKMs are in charge of creating and deploying data manipulation Web Services to your Service Oriented Architecture (SOA) infrastructure. SKMs are set on a Model. They define the different operations to generate for each datastores web service. Unlike other KMs, SKMs do no generate an executable code but rather the Web Services deployment archive files. SKMs are designed to generate Java code using Oracle Data Integrator’s framework for Web Services. The code is then compiled and eventually deployed on the Application Server’s containers.

1) SKM HSQL

2) SKM IBM UDB

3) SKM Informix

4) SKM Oracle

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Working With Change Data Capture

Posted on April 7, 2011

Changed Data Capture

Purpose of CDC is to enable applications to process changed data only. CDC enables ODI to track changes in source data caused by other applications. When running integration interfaces, ODI can avoid processing unchanged data in the flow. Loads will process only changes since the last load. The volume of data to be processed is dramatically reduced.

Reducing the source data flow to only changed data is useful in many contexts, such as data synchronization and replication. It is essential when setting up an event-oriented architecture for integration. In such architecture, applications make changes in the data (“Customer Deletion”, “New Purchase Order”) during a business process. These changes are captured by Oracle Data Integrator and transformed into events that are propagated throughout the information system.

CDC Techniques

1)Trigger based: ODI will create and maintain triggers to keep track of the changes.

2) Logs based: ODI retrieves changes from the database logs (Oracle, AS/400).

3) Time stamp based: Processes written with ODI can filter the data by comparing the time stamp value with the last load time (cannot process

deletes)

4) Sequence number: If the records are numbered in sequence, ODI can filter the data based on the last value loaded (cannot process updates

and deletes).

Changed Data Capture is performed by journalizing models. Journalizing a model consists of setting up the infrastructure to capture the changes (inserts, updates and deletes) made to the records of this model‟s datastores.

Oracle Data Integrator supports two journalizing modes:

•Simple Journalizing tracks changes in individual datastores in a model.

•Consistent Set Journalizing tracks changes to a group of the model‟s datastores, taking into account the referential integrity between these datastores. The group of datastores journalized in this mode is called a Consistent Set.

The Journalizing Components

The journalizing components are:

•Journals: Where changes are recorded. Journals only contain references to the changed records along with the type of changes (insert/update,

•Capture processes: Journalizing captures the changes in the source datastores either by creating triggers on the data tables, or by using

database-specific programs to retrieve log data from data server log files.

•Subscribers: CDC uses a publish/subscribe model. Subscribers are entities (applications, integration processes, etc) that use the changes tracked

on a datastore or on a consistent set. They subscribe to a model‟s CDC to have the changes tracked for them. Changes are captured only if there is at least one subscriber to the changes. When all subscribers have consumed the captured changes, these changes are discarded from the journals.

•Journalizing views: Provide access to the changes and the changed data captured. They are used by the user to view the changes captured, and

by integration processes to retrieve the changed data.

These components are implemented in the journalizing infrastructure

Setting up Journalizing:

This is the basic process for setting up CDC on an Oracle Data Integrator data model. Each of these steps is described in more detail below.

1.Set the CDC parameters 2.Add the datastores to the CDC

3.For consistent set journalizing, arrange the datastores in order 4.Add subscribers

5.Start the journals

Journalizing Tools:

Oracle Data Integrator provides a set of tools that can be used in journalizing to refresh information on the captured changes or trigger other processes:

•SnpsWaitForData waits for a number of rows in a table or a set of tables.

•SnpsWaitForLogData waits for a certain number of modifications to occur on a journalized table or a list of journalized tables. This tool calls

SnpsRefreshJournalCount to perform the count of new changes captured.

•SnpsWaitForTable waits for a table to be created and populated with a pre-determined number of rows.

•SnpsRetrieveJournalData retrieves the journalized events for a given table list or CDC set for a specified journalizing subscriber. Calling this

tool is required if using Database-Specific Processes to load journalizing tables. This tool needs to be used with specific knowledge modules.

•SnpsRefreshJournalCount refreshes the number of rows to consume for a given table list or CDC set for a specified journalizing subscriber.

Implementing Changed Data Capture:

Step:1) Import the appropriate JKM in the project.

Click the Projects tab. Expand the Procedure-Demo > Knowledge Modules node, right-click Journalization (JKM), and select Import Knowledge Modules.

Step:2) In the Models tab, create a new model named Oracle_relational_01. For Technology, enter: Oracle. Select the logical schema

Sales_Order. Click the Reverse Engineer tab and set Context to development. Verify the setting, as shown in the following screen. Click the Journalizing tab.

Step: 3) In the Knowledge Module menu, select JKM Oracle Simple. Procedure-Demo, as shown in the following screen. Click the Save to save

Step: 4) Reverse-engineer the model Oracle_Relational_01. Expand this model and verify its structure as follows.

Step: 5) Set up the CDC Infrastructure. You will start the CDC on the EMPLOYEE table in the Oracle_Relational_01 model.

To add the table to CDC, expand the Oracle_Relational_01 model, right-click the EMPLOYEE table, and select Change Data Capture > Add to CDC. Click Yes to confirm.

Step: 6) Click the Refresh icon. The small yellow clock icon is added to the table.

Step: 8) you use the default subscriber SUNOPSIS. For that reason, you do not have to add another subscriber. Click OK to confirm that your

subscriber is SUNOPSIS. In the Information window, click OK again. Wait several seconds, then click Refresh and verify that the tiny clock icon at the EMPLOYEE table is green now. This means that your journal has started properly.

Step: 9) Click the ODI Operator icon to open the Operator. Click Refresh. Select All Executions and verify that the EMPLOYEE session

executed successfully.

Step: 10) View the data and the changed data.

Step: 11) Select the row with Employee_Key = 10. Change the value of the NAME2 column to “Symond”. Similarly, select the row with

Employee_Key = 15, and then change the value to “jacob”. Save your changes and close the tab.

Step: 12) Right-click the table again and select View Data. Scroll down, and verify that the rows are modified. Close the tab.

To verify that your changed data is captured, right-click EMPLOYEE, and select Change Data Capture > Journal Data. Find the captured changed records in the journal data. Close the tab.

Done !

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Oracle Data Integrator 11g Knowledge

Modules Description

Posted on March 26, 2011

RKM Oracle

Reverse-engineers tables, views, columns, primary keys, non unique indexes and foreign keys.

JKM Oracle 10g Consistent (Streams)

Creates the journalizing infrastructure for consistent set journalizing on Oracle 10g tables, using Oracle Streams.

JKM Oracle 11g Consistent (Streams)

Creates the journalizing infrastructure for consistent set journalizing on Oracle 11g tables, using Oracle Streams.

JKM Oracle Consistent

Creates the journalizing infrastructure for consistent set journalizing on Oracle tables using triggers.

JKM Oracle Consistent (Update Date)

Creates the journalizing infrastructure for consistent set journalizing on Oracle tables using triggers based on a Last Update Date column on the source tables.

JKM Oracle Simple

Creates the journalizing infrastructure for simple journalizing on Oracle tables using triggers.

JKM Oracle to Oracle Consistent (OGG)

Creates and manages the ODI CDC framework infrastructure when using Oracle GoldenGate for CDC. See Chapter 26, “Oracle GoldenGate” for more information.

CKM Oracle

Checks data integrity against constraints defined on an Oracle table.

LKM File to Oracle (EXTERNAL TABLE)

Loads data from a file to an Oracle staging area using the EXTERNAL TABLE SQL Command.

LKM File to Oracle (SQLLDR)

Loads data from a file to an Oracle staging area using the SQL*Loader command line utility.

LKM MSSQL to Oracle (BCP SQLLDR)

Loads data from a Microsoft SQL Server to Oracle database (staging area) using the BCP and SQL*Loader utilities.

LKM Oracle BI to Oracle (DBLINK)

Loads data from any Oracle BI physical layer to an Oracle target database using database links. See Chapter 17, “Oracle Business Intelligence Enterprise Edition” for more information.

LKM Oracle to Oracle (DBLINK)

Loads data from an Oracle source database to an Oracle staging area database using database links.

LKM Oracle to Oracle (datapump)

Loads data from an Oracle source database to an Oracle staging area database using external tables in the datapump format.

LKM SQL to Oracle

LKM SAP BW to Oracle (SQLLDR)

Loads data from SAP BW systems to an Oracle staging using SQL*Loader utilities. See the Oracle Fusion Middleware Application Adapters Guide for Oracle Data Integrator for more information.

LKM SAP ERP to Oracle (SQLLDR)

Loads data from SAP ERP systems to an Oracle staging using SQL*Loader utilities. See the Oracle Fusion Middleware Application Adapters Guide for Oracle Data Integrator for more information.

IKM Oracle AW Incremental Update

Integrates data in an Oracle target table in incremental update mode and is able to refresh a Cube in an Analytical Workspace. See Chapter 21, “Oracle OLAP” for more information.

IKM Oracle Incremental Update

Integrates data in an Oracle target table in incremental update mode.

IKM Oracle Incremental Update (MERGE)

Integrates data in an Oracle target table in incremental update mode, using a MERGE statement.

IKM Oracle Incremental Update (PL SQL)

Integrates data in an Oracle target table in incremental update mode using PL/SQL.

IKM Oracle Multi Table Insert

Integrates data from one source into one or many Oracle target tables in append mode, using a multi-table insert statement (MTI).

IKM Oracle Slowly Changing Dimension

Integrates data in an Oracle target table used as a Type II Slowly Changing Dimension.

IKM Oracle Spatial Incremental Update

Integrates data into an Oracle (9i or above) target table in incremental update mode using the MERGE DML statement. This module supports the SDO_GEOMETRY datatype.

Integrates data from one Oracle instance into an Oracle target table on another Oracle instance in control append mode.

This IKM is typically used for ETL configurations: source and target tables are on different Oracle instances and the interface‟s staging area is set to the logical schema of the source tables or a third schema.

SKM Oracle

Generates data access Web services for Oracle databases. See “Working with Data Services” in the Oracle Fusion Middleware Developer‟s Guide for Oracle Data Integrator for information about how to use this SKM.

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Extracting Hyperion Financial Management

Metadata to Oracle Data Integrator

Posted on March 26, 2011

Step: 1) Go to Start—>Program Files—>Oracle—>Oracle Data Integrator explore ODI and login to work repository.

Step: 2) After successfully login to work repository go to Topology Navigator select Physical Architecture Tab and select Technology and expand it. Go to the Hyperion Financial Management Right Click and select „New Data Server‟.

Step: 3) In the definition tab enter the following details as shown in the picture below: Name: Appropriate name to data server

Cluster (Data Server): System name User: User Name

Password: password

Step: 4) Click on Save it will ask you to create physical schema press „OK‟.

Step: 5) In Technology Tab go to Hyperion Financial Management expand it and select newly create data server Right Click and select „New Physical schema‟.

Step: 7) Click on Save it will ask you to specify the context press „OK‟.

Step: 8) Go to the Logical Architecture tab Expand Technologies and select Hyperion Financial Management Right-click and select „New Logical Schema‟.

Step: 9) Give appropriate name to logical schema and set the Context to Hyperion Financial Management physical schema.

Step: 10) Click on „Save‟.

Step: 12) Click on „Save‟. You can check in the project tab

Step: 13) Expand project go to knowledge module right click and import following knowledge modules.

RKM Hyperion Financial Management LKM File to SQL

LKM Hyperion Financial Management Members To SQL LKM Hyperion Financial Management Data To SQL IKM SQL to Hyperion Financial Management Data IKM SQL to Hyperion Financial Management Dimension IKM SQL to File Append

Step: 15) „Close‟.

Step: 16) Now go to the model tab and create new model folder.

Step: 17) Go to the model tab and create new model.

Step: 19) „Save‟

Step:20) Newly created Model will be available for Reverse Engineering go to Model tab select Hyperion planning model and Right Click and select Reverse Engineers. Before Reverse Engineer the models make sure your agent services are running if not start it with following command:

C:\oracle\Middleware\Oracle_ODI1\oracledi\agent\bin>agent –NAME=localagent

Press „OK‟.

Step: 22) Go to the Operator Tab check whether the Execution run successfully or not.

If all the checks are green that means your model reversed successfully.

Step: 23) Go to the Designer and open model tab expand Hyperion Financial Management model again. You can check all the dimensions are visible there from your HFM application

Done !

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Configuring ODI for integrating with

Hyperion Financial Management Application

Posted on March 26, 2011

I will be using Single-machine architecture; machine will be hosting ODI and hosting HFM and EPM foundation (Workspace and shared services). I have created a FM application named SAMPLE that is based on the “Simple Demo” information that can be found in “Hyperion\products\Financial Management\Sample Apps\Simple Demo\” of the HFM installation.

The machine is windows based as that is a pre-requisite for HFM and also the HFM client that has to be installed on the ODI machine. The EPM version installed is 11.1.1.3

We need to perform some work around solutions for integrating ODI 11g with EPMA 11.1.1.3.

Step: 1) Go to directory C:\oracle\Middleware\Oracle_ODI1\oracledi\agent\lib Copy the HFMDriver.dll file and pest it to directory C:\oracle\Middleware\Oracle_ODI1\oracledi\agent\drivers

Step: 2) If you will use the “Local Agent” you will need to add the driver location to the windows environment variable (Path). C:\oracle\Middleware\Oracle_ODI1\oracledi\agent\drivers

Once you have added the location make sure you restart all the ODI components to pick up the driver or you will continue to receive the error message.

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Creating and Connecting to ODI Master and

Work Repositories

Posted on March 25, 2011 1

The first steps to setting up Oracle Data Integrator are to create the Master repository, connect to the Master repository, create the Work repository, and then connect to the Work repository

Step:2) Connecting to the RDBMS (Oracle 10g XE)

Step:3) Creating the RDBMS Schema/User (Oracle 10g XE) for the Master Repository

i.On the Oracle Database Express Edition Home screen, select SQL Commands > Enter Command from the SQL drop-down list.

Create the schemas by executing the following SQL commands: create user identified by ; grant dba, connect, create session to ;

SQL> create user bispmaster identified by password; SQL> grant dba,connect,create session to bispmaster;

In the URL field, enter the following URL: jdbc:oracle:thin:@bispcognos:1521:xe, and then enter the User as bispmaster and Password as password(This is in our condition). In the Technology field, select Oracle. Click the Test Connection button and verify successful connection. Click Next. Click OK on Master Repository Creation Wizard screen.

The SQL command is executed in the command window. If the Master repository creation is successful, you will see the following message. Click OK. The ODI Master repository is now created.

Step:5) Connecting to the ODI Master Repository

Configure Repository Connections with the parameters provided in the following screen. Click the Test button. Verify successful connection and click OK. Click OK to save the connection.

A relational schema must be created for each repository. The following steps walk you through creating the relational schema for the ODI Work repository.

Step:1)Connecting to the RDBMS

If not opened, open the Oracle XE Database Home page: Start > All Programs > Oracle Database 10g Express Edition > Go to Database Home page.

Step:2) Creating the RDBMS Schema/User (Oracle 10g XE) for the Work Repository

On the Oracle Database Express Edition Home screen, select SQL Commands > Enter Command from the SQL drop-down list.

Create the schemas by executing the following SQL commands: create user identified by ; grant dba, connect, create session to ;

SQL> create user bispwork identified by password; SQL> grant dba,connect,create session to bispwork;

Step:3) Creating the ODI Work Repository

In ODI, click the Topology Navigator tab and then click to the Repositories panel. Right-click the Work Repositories node and select New Work Repository. The Create Work Repository Wizard opens.

In the screen that follows, enter the parameters shown in the following screen. Click the Test button. Verify successful connection and click OK. Click Next.

In the Create Work Repository Login window, click Yes. Enter the Login name: WORK_REPO as shown on the screenshot. Click OK. Verify that the newly created Work repository is now in the work repositories tree view

Now you disconnect from the Master repository and connect to the Work repository. Click ODI menu and select Disconnect “Master Repository”.

Click Connect to Repository. Select “WORK_REPO” from the Login Name drop-down list. Enter Password: SUNOPSIS. Click OK. Click the Designer tab. The following ODI Designer screen appears.