Difference between Plannning Buffer and Delta Buffer in IP

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• Difference Between Update Queue and Delta Queue

  Hi Experts ,
  Could u brief out the difference between Extraction Queue , Update Queue and Delta Queue  ?

  Hi
  a) Serialized V3 Update(If you set this as your delta mode then data will populated into extraction queue tables)
  This is the conventional update method in which the document data is collected in the sequence of attachment and transferred to BW by batch job.The sequence of the transfer does not always match the sequence in which the data was created.
  b) Queued Delta(If you set this as your delta mode then data will be populated into update queue tables)
  In this mode, extraction data is collected from document postings in an extraction queue from which the data is transferred into the BW delta queue using a periodic collective run. The transfer sequence is the same as the sequence in which the data was created
  Delta queue is a table which collects data from extraction queue/update queue tables based on the frequency you have set(daily/hourly etc)..from these tables we will get delta records to bw with infopackage delta run..
  Hope it helps
  Thanks
  Teja

• Differences Between Optimizer Solution and Planner Solution in Project Server Events

  Dear All,
  Does anyone know the differences between Optimizer Solution and Planner Solution in Project Server? 
  In http://msdn.microsoft.com/en-us/library/office/gg204879(v=office.15).aspx and http://msdn.microsoft.com/en-us/library/office/gg200978(v=office.15).aspx, they stated same definitions for both Optimizer Solution and Planner Solution.
  Thank you.

  Not entirely sure, but I'd guess they are the same.  This is probably a relic of the old Portfolio Server which had Planner and Optimizer as separate modules.  My guess is that some of that got grandfathered in to Project Server, but due
  to functionality creep, ended up meaning pretty much the same thing.
  Andrew Lavinsky [MVP] Blog: http://azlav.umtblog.com Twitter: @alavinsky

• Difference between Generic extraction and Generic Delta

  Hi Experts,
  Pleasee give of some information below  query:
  1) Difference between Generic extraction and Generic Delta.
  2) How to achieve Generic delta.
  3) When we go for Generic delta instead of generic extraction.
  Advance ThankU. Points vl be assigned.
  Thanks,
  Ragu.R

  Hi,
  Generic delta is the delta load done using Generic DS.
  Generic extraction
  Usage:
  1. When the standard extractors are not supporting the extraction what you need. If SAP does not have a standard extractor for your need to get data from R3, you would have to go for generic extractor.
  2. If you create a custom object say by combining certain base tables in R3 say custom tables ZTAB1 and ZTAB2. These two tables are not SAP provided tables and there will not be any standard extractors. So cases like this you will have to go for generic extractors.
  How:
  You have to use RSO2 transaction and you can also set delta based on, one of the three characteristics such as timestamp, calday or pointer (a sequence no).
  once you create it and activate it. The extractor will be available in ROOSOURCE - (table in R3 where all the data sources are available).
  Refer:
  /people/siegfried.szameitat/blog/2005/09/29/generic-extraction-via-function-module
  http://help.sap.com/saphelp_nw04/helpdata/en/3f/548c9ec754ee4d90188a4f108e0121/content.htm
  https://www.sdn.sap.com/irj/servlet/prt/portal/prtroot/docs/library/uuid/84bf4d68-0601-0010-13b5-b062adbb3e33
  Generic Extraction via Function Module
  /people/siegfried.szameitat/blog/2005/09/29/generic-extraction-via-function-module
  thanks,
  JituK

• Difference between Low level and Normal IMAQ ?

  There are two options in IMAQ palette a low level and a normal one. Both have the same function names and the same icons the only difference being the balck and white icon of low level functions and colored icons of the normal functions. What is the difference between these two and what is the need of making a low level palette of functions ?
  Regards
  Asad Tirmizi
  Design Engineer
  Institute of Avionics and Aeronautics
  " Its never too late to be, what u want to be"
  Using LabVIEW 8.2

  Low level imaq functions gives you relatively more function to control the hardware. Buffer functions is one which is not there on the high level palatte

• What is the difference between undo tablespace and online redo log files.

  what is the difference between undo tablespace and online redo log files. I am confused
  as per my knowledge undo tablespace is used to store the undo information when a table is being updated so that, just incase we need to rollback a transaction we know what was present in the table earlier.
  when a transaction fails the SMON performs the rollback of the data.
  This undo data is stored in the undo tablespace and read consistency if any is enforced.
  is my understanding till here correct?
  Now, can this undo data/before image not be stored in the redo log buffer and online redolog files?
  can redo-log files not store this information?
  in fact, is it that when undo tablespaces exist in a database, the undo data/before image is stored in both the undo tablespace and also the redo log files?
  kindly clarify my doubt.
  thank you.

  This question has been asked many times before. The answer is always the same.
  Yes, redo contains the before image of data (and the after-image). Therefore, it **COULD** be used to roll back a transaction.
  BUT... Redo is written sequentially. Using it to rollback your transaction would involve reading through all the redo written by maybe thousands of other people. It would be painfully slow.
  Your transaction is, however, directly linked to just the UNDO that it generates (which is JUST the before image of the data). So, your undo is your undo and doesn't share space with anyone else's undo. Therefore, using it to roll back YOUR transaction is fast.
  The fact that undo is only the before image of the data also makes it faster than wading through a sea of before and AFTER images as you'd find in redo. About twice as fast, in fact, since there's half the data. Roughly.
  Redo also gets written and flushed to disk whenever there's a commit, 3 seconds are up or too much (1MB, actually) redo gets generated between flushes caused by other factors. Your redo gets flushed when those things happen, even if you haven't actually committed your transaction. And redo logs recycle themselves, meaning that your redo -even if your transaction hasn't been committed yet- can be over-written by later transactions. Try rolling back when that's happened, if redo was the source of your rollback data!
  Undo, however, cannot be over-written if the transaction has not been committed. Ever. If you don't commit for three years, there will be three years' undo stored in your database (assuming you had the space, of course!).
  I could go on, but that will do. Redo is there fore RECOVERY, after catastrophe. Undo is there for read-consistency (and the occasional change of mind). Two different functions. Two different mechanisms. Each one highly tuned to doing what it does, why it does it, most efficiently and effectively.

• What is the difference between full checkpoint and incremental checkpoint?

  What is the difference between full checkpoint and incremental checkpoint?
  And what is checkpoint queue?
  Can someone clarify these concepts?
  Thanks!

  Hi,
  there are different types of checkpoints:
  - Full checkpoint:
  => DBWR writes all dirty buffers from the Buffer cache to the datafiles and CKPT retrieves a new Checkpoint Change Number from a sys owned sequence and writes this number to all file headers and the controlfile.
  -- can be triggered by different events, like a logswitch, a manual checkpoint (alter system ..), a shutdown and so on
  This is the setup point for SMON for a crash recovery.
  - Partial checkpoint:
  => DBWR writes all dirty buffers of a singel tablespace from the Buffer cache to the datafiles and CKPT retrieves a new Checkpoint Change Number from a sys owned sequence and writes this number to all file headers and the controlfile.
  -- can e triggered by an ALTER TABLESPACE OFFLINE, ALTER TABLESPACE READ ONLY, ALTER TABLESPACE BEGIN BACKUP statement.
  Incremental checkpoint:
  number to all file headers and the controlfile.
  -- can be triggered by different events, like a logswitch, a manual checkpoint (alter system ..), a shutdown and so on
  - Partial checkpoint:
  => DBWR writes all dirty buffers of a single tablespace from the Buffer cache to the datafiles and CKPT retrieves a new Checkpoint Change Number from a sys owned sequence and writes this number to all file headers and the controlfile.
  -- frequency is determined by FAST_START_MTTR_TARGET parameter (new feature to Oracle 9i), with wich you can specify a time in seconds which SMON is allowed to take maximal for a Crash Recovery until the database must be open again.
  Dapending on the system you have SMON must calculate the maximum number of Redolog-blocks which it can manage to recover in the specified number of seconds. It will then create so called incremental checkpoints which will be tracked in the so called checkpoint queue in memory.
  FAST_START_MTTR_TARGET is auto-tuned in Oracle 10g and Oracle tries to manage (incremental) checkpoint in a fashion that a minimum of I/Os are caused and a minimum time for crash recovery is needed.
  If you set LOG_CHECKPOINTS_TO_ALERT to TRUE you will find checkpoint information in the alertSID.log file. You will see FULL and INCREMENTAL checkpoints then.
  Hope this clarifies your question,
  Lutz Hartmann

• Differences between Procedural ABAP and OOPs ABAP

  Hi Friends,
  Can any one explain the differences between Procedural ABAP and OOPs ABAP in brief ? pls explain the most important ( atleast 3 or 4 points ). pls don't give me any other links, i will appreciate for good responses... and will be awarded with full points...
  Thanks and Regards
  Vijaya

  Hi
  Core ABAP (procedural) works with Event driven, subroutine driven one
  OOPS ABAP works on the OOPS concepts like Inheritance, polymorphism,abstraction and encapsulation.
  see the doc
  ABAP is one of many application-specific fourth-generation languages (4GLs) first developed in the 1980s. It was originally the report language for SAP R/2, a platform that enabled large corporations to build mainframe business applications for materials management and financial and management accounting. ABAP used to be an abbreviation of Allgemeiner Berichtsaufbereitungsprozessor, the German meaning of "generic report preparation processor", but was later renamed to Advanced Business Application Programming. ABAP was one of the first languages to include the concept of Logical Databases (LDBs), which provides a high level of abstraction from the basic database level.
  The ABAP programming language was originally used by SAP developers to develop the SAP R/3 platform. It was also intended to be used by SAP customers to enhance SAP applications – customers can develop custom reports and interfaces with ABAP programming. The language is fairly easy to learn for programmers but it is not a tool for direct use by non-programmers. Good programming skills, including knowledge of relational database design and preferably also of object-oriented concepts, are required to create ABAP programs.
  ABAP remains the language for creating programs for the client-server R/3 system, which SAP first released in 1992. As computer hardware evolved through the 1990s, more and more of SAP's applications and systems were written in ABAP. By 2001, all but the most basic functions were written in ABAP. In 1999, SAP released an object-oriented extension to ABAP called ABAP Objects, along with R/3 release 4.6.
  SAP's most recent development platform, NetWeaver, supports both ABAP and Java.
  Implementation
  Where does the ABAP Program Run?
  All ABAP programs reside inside the SAP database. They are not stored in separate external files like Java or C++ programs. In the database all ABAP code exists in two forms: source code, which can be viewed and edited with the ABAP workbench, and "compiled" code ("generated" code is the more correct technical term), which is loaded and interpreted by the ABAP runtime system. Code generation happens implicitly when a unit of ABAP code is first invoked. If the source code is changed later or if one of the data objects accessed by the program has changed (e.g. fields were added to a database table), then the code is automatically regenerated.
  ABAP programs run in the SAP application server, under control of the runtime system, which is part of the SAP kernel. The runtime system is responsible for processing ABAP statements, controlling the flow logic of screens and responding to events (such as a user clicking on a screen button). A key component of the ABAP runtime system is the Database Interface, which turns database-independent ABAP statements ("Open SQL") into statements understood by the underlying DBMS ("Native SQL"). The database interface handles all the communication with the relational database on behalf of ABAP programs; it also contains extra features such as buffering of frequently accessed data in the local memory of the application server.
  Basis
  Basis sits between ABAP/4 and Operating system.Basis is like an operating system for R/3. It sits between the ABAP/4 code and the computer's operating system. SAP likes to call it middleware because it sits in the middle, between ABAP/4 and the operating system. Basis sits between ABAP/4 and the operating system. ABAP/4 cannot run directly on an operating system. It requires a set of programs (collectively called Basis) to load, interpret, and buffer its input and output. Basis, in some respects, is like the Windows environment. Windows starts up, and while running it provides an environment in which Windows programs can run. Without Windows, programs written for the Windows environment cannot run. Basis is to ABAP/4 programs as Windows is to Windows programs. Basis provides the runtime environment for ABAP/4 programs. Without Basis, ABAP/4 programs cannot run. When the operator starts up R/3, you can think of him as starting up Basis. Basis is a collection of R/3 system programs that present you with an interface. Using this interface the user can start ABAP/4 programs. To install Basis, an installer runs the program r3inst at the command-prompt level of the operating system. Like most installs, this creates a directory structure and copies a set of executables into it. These executables taken together as a unit form Basis.
  To start up the R/3 system, the operator enters the startsap command. The Basis executables start up and stay running, accepting requests from the user to run ABAP/4 programs.
  ABAP/4 programs run within the protective Basis environment; they are not executables that run on the operating system. Instead, Basis reads ABAP/4 code and interprets it into operating system instructions. ABAP/4 programs do not access operating system functions directly. Instead, they use Basis functions to perform file I/O and display data in windows. This level of isolation from the operating system enables ABAP/4 programs to be ported without modification to any system that supports R/3. This buffering is built right into the ABAP/4 language itself and is actually totally transparent to the programmer.
  Basis makes ABAP/4 programs portable. The platforms that R/3 can run on are shown in Table. For example, if you write an ABAP/4 program on Digital UNIX with an Informix database and an OSF/Motif interface, that same program should run without modification on a Windows NT machine with an Oracle database and a Windows 95 interface. Or, it could run on an AS/400 with a DB2 database using OS/2 as the front-end.
  SAP also provides a suite of tools for administering the Basis system. These tools perform tasks such as system performance monitoring, configuration, and system maintenance. To access the Basis administration tools from the main menu, choose the path Tools->Administration.
  Platforms and Databases Supported by R/3
  Operating Systems Supported Hardware Supported Front-Ends Supported Databases
  AIX SINIX IBM SNI SUN Win 3.1/95/NT DB2 for AIX
  SOLARIS HP-UX Digital HP OSF/Motif Informix-Online
  Digital-UNIX Bull OS/2 Oracle 7.1
  Windows NT AT&T Compaq Win 3.1/95/NT Oracle 7.1
  Bull/Zenith OSF/Motif SQL Server 6.0
  HP (Intel) SNI OS/2 ADABAS D
  OS/400 AS/400 Win95 OS/2 DB2/400
  SAP Systems and Landscapes
  All SAP data exists and all SAP software runs in the context of an SAP system. A system consists of a central relational database and one or more application servers ("instances") accessing the data and programs in this database. A SAP system contains at least one instance but may contain more, mostly for reasons of sizing and performance. In a system with multiple instances, load balancing mechanisms ensure that the load is spread evenly over the available application servers.
  Installations of the Web Application Server (landscapes) typically consist of three systems: one for development, one for testing and quality assurance, and one for production. The landscape may contain more systems, e.g. separate systems for unit testing and pre-production testing, or it may contain fewer, e.g. only development and production, without separate QA; nevertheless three is the most common configuration. ABAP programs are created and undergo first testing in the development system. Afterwards they are distributed to the other systems in the landscape. These actions take place under control of the Change and Transport System (CTS), which is responsible for concurrency control (e.g. preventing two developers from changing the same code at the same time), version management and deployment of programs on the QA and production systems.
  The Web Application Server consists of three layers: the database layer, the application layer and the presentation layer. These layers may run on the same or on different physical machines. The database layer contains the relational database and the database software. The application layer contains the instance or instances of the system. All application processes, including the business transactions and the ABAP development, run on the application layer. The presentation layer handles the interaction with users of the system. Online access to ABAP application servers can go via a proprietary graphical interface, the SAPGUI, or via a Web browser.
  Transactions
  We call an execution of an ABAP program using a transaction code a transaction. There are dialog, report, parameter, variant, and as of release 6.10, OO transactions. A transaction is started by entering the transaction code in the input field on the standard toolbar, or by means of the ABAP statements CALL TRANSACTION or LEAVE TO TRANSACTION. Transaction codes can also be linked to screen elements or menu entries. Selecting such an element will start the transaction.
  A transaction code is simply a twenty-character name connected with a Dynpro, another transaction code, or, as of release 6.10, a method of an ABAP program. Transaction codes linked with Dynpros are possible for executable programs, module pools, and function groups. Parameter transactions and variant transactions are linked with other transaction codes. Transaction codes that are linked with methods are allowed for all program types that can contain methods. Transaction codes are maintained in transaction SE93.
  So, a transaction is nothing more than the SAP way of program execution—but why is it called “transaction”? ABAP is a language for business applications and the most important features of business applications were and still are are transactions. Since in the early days of SAP, the execution of a program often meant the same thing as carrying out a business transaction, the terms transaction and transaction code were chosen for program execution. But never mix up the technical meaning of a transaction with business transactions. For business transactions, it is the term LUW (Logical Unit of Work) that counts. And during one transaction (program execution), there can be many different LUW’s.
  Let’s have a look at the different kind of transactions:
  Dialog Transaction
  These are the most common kind of transactions. The transaction code of a dialog transaction is linked to a Dynpro of an ABAP program. When the transaction is called, the respective program is loaded and the Dynpro is called. Therefore, a dialog transaction calls a Dynpro sequence rather than a program. Only during the execution of the Dynpro flow logic are the dialog modules of the ABAP program itself are called. The program flow can differ from execution to execution. You can even assign different dialog transaction codes to one program.
  Parameter Transaction
  In the definition of a parameter transaction code, a dialog transaction is linked with parameters. When you call a parameter transaction, the input fields of the initial Dynpro screen of the dialog transaction are filled with parameters. The display of the initial screen can be inhibited by specifying all mandatory input fields as parameters of the transaction.
  Variant Transaction
  In the definition of a variant transaction code, a dialog transaction is linked with a transaction variant. When a variant transaction is accessed, the dialog transaction is called and executed with the transaction variant. In transaction variants, you can assign default values to the input fields on several Dynpro screens in a transaction, change the attributes of screen elements, and hide entire screens. Transaction variants are maintained in transaction SHD0.
  Report Transaction
  A report transaction is the transaction code wrapping for starting the reporting process. The transaction code of a report transaction must be linked with the selection screen of an executable program. When you execute a report transaction, the runtime environment internally executes the ABAP statement SUBMIT—more to come on that.
  OO Transaction
  A new kind of transaction as of release 6.10. The transaction code of an OO transaction is linked with a method of a local or global class. When the transaction is called, the corresponding program is loaded, for instance methods an object of the class is generated and the method is executed.
  Types of ABAP programs
  In ABAP, there are two different types of programs:
  Report programs(Executable pools)
  A Sample ReportReport programs AKA Executable pools follow a relatively simple programming model whereby a user optionally enters a set of parameters (e.g. a selection over a subset of data) and the program then uses the input parameters to produce a report in the form of an interactive list. The output from the report program is interactive because it is not a passive display; instead it enables the user, through ABAP language constructs, to obtain a more detailed view on specific data records via drill-down functions, or to invoke further processing through menu commands, for instance to sort the data in a different way or to filter the data according to selection criteria. This method of presenting reports has great advantages for users who must deal with large quantities of information and must also have the ability to examine this information in highly flexible ways, without being constrained by the rigid formatting or unmanageable size of "listing-like" reports. The ease with which such interactive reports can be developed is one of the most striking features of the ABAP language.
  The term "report" is somewhat misleading in the sense that it is also possible to create report programs that modify the data in the underlying database instead of simply reading it.
  A customized screen created using Screen Painter,which is one of the tool available in ABAP workbench(T-code = SE51).
  Online programs
  Online programs (also called module pools) do not produce lists. These programs define more complex patterns of user interaction using a collection of screens. The term “screen” refers to the actual, physical image that the users sees. Each screen also has a “flow logic”; this refers to the ABAP code invoked by the screens, i.e. the logic that initializes screens, responds to a user’s requests and controls the sequence between the screens of a module pool. Each screen has its own Flow Logic, which is divided into a "PBO" (Process Before Output) and "PAI" (Process After Input) section. In SAP documentation the term “dynpro” (dynamic program) refers to the combination of the screen and its Flow Logic.
  Online programs are not invoked directly by their name, but are associated with a transaction code. Users can then invoke them through customizable, role-dependent, transaction menus.
  Apart from reports and online programs, it is also possible to develop sharable code units such as class libraries, function libraries and subroutine pools.
  Subroutine Pools
  Subroutine pools, as the name implies, were created to contain selections of subroutines that can be called externally from other programs. Before release 6.10, this was the only way subroutine pools could be used. But besides subroutines, subroutine pools can also contain local classes and interfaces. As of release 6.10, you can connect transaction codes to methods. Therefore, you can now also call subroutine pools via transaction codes. This is the closest to a Java program you can get in ABAP: a subroutine pool with a class containing a method – say – main connected to a transaction code!
  Type Pools
  Type pools are the precursors to general type definitions in the ABAP Dictionary. Before release 4.0, only elementary data types and flat structures could be defined in the ABAP Dictionary. All other types that should’ve been generally available had to be defined with TYPES in type pools. As of release 4.0, type pools were only necessary for constants. As of release 6.40, constants can be declared in the public sections of global classes and type pools can be replaced by global classes.
  Class Pools
  Class pools serve as containers for exactly one global class. Besides the global class, they can contain global types and local classes/interfaces to be used in the global class. A class pool is loaded into memory by using one of its components. For example, a public method can be called from any ABAP program or via a transaction code connected to the method. You maintain class pools in the class builder.
  Interface Pools
  Interface pools serve as containers for exactly one global interface—nothing more and nothing less. You use an interface pool by implementing its interface in classes and by creating reference variables with the type of its interface. You maintain interface pools in the class builder.
  ABAP Workbench
  The ABAP Workbench contains different tools for editing Repository objects. These tools provide you with a wide range of assistance that covers the entire software development cycle. The most important tools for creating and editing Repository objects are:
  ABAP Editor for writing and editing program code
  ABAP Dictionary for processing database table definitions and retrieving global types
  Menu Painter for designing the user interface (menu bar, standard toolbar, application toolbar, function key assignment)
  Screen Painter for designing screens (dynamic programs) for user dialogs
  Function Builder for displaying and processing function modules (routines with defined interfaces that are available throughout the system)
  Class Builder for displaying and processing ABAP Objects classes
  The ABAP Dictionary
  Enforces data integrity
  Manages data definitions without redundancy
  Is tightly integrated with the rest of the ABAP/4 Development Workbench.
  Enforcing data integrity is the process of ensuring that data entered into the system is logical, complete, and consistent. When data integrity rules are defined in the ABAP/4 Dictionary, the system automatically prevents the entry of invalid data. Defining the data integrity rules at the dictionary level means they only have to be defined once, rather than in each program that accesses that data.
  The following are examples of data lacking integrity:
  A date field with a month value of 13
  An order assigned to a customer number that doesn’t exist
  An order not assigned to a customer
  Managing data definitions without redundancy is the process of linking similar information to the same data definition. For example, a customer database is likely to contain a customer’s ID number in several places. The ABAP Dictionary provides the capability of defining the characteristics of a customer ID number in only one place. That central definition then can be used for each instance of a customer ID number.
  The ABAP Dictionary’s integration with the rest of the development environment enables ABAP programs to automatically recognize the names and characteristics of dictionary objects.
  Additionally, the system provides easy navigation between development objects and dictionary definitions. For example, as a programmer, you can double-click on the name of a dictionary object in your program code, and the system will take you directly to the definition of that object in the ABAP/4 Dictionary.
  When a dictionary object is changed, a program that references the changed object will automatically reference the new version the next time the program runs. Because ABAP is interpreted, it is not necessary to recompile programs that reference changed dictionary objects.
  ABAP Syntax
  The syntax of the ABAP programming language consists of the following elements:
  Statements
  An ABAP program consists of individual ABAP statements. Each statement begins with a keyword and ends with a period.
  "Hello World" PROGRAM
  WRITE 'Hello World'.
  This example contains two statements, one on each line. The keywords are PROGRAM and WRITE. The program displays a list on the screen. In this case, the list consists of the line "My First Program".
  The keyword determines the category of the statement. For an overview of the different categories, refer to ABAP Statements.
  Formatting ABAP Statements
  ABAP has no format restrictions. You can enter statements in any format, so a statement can be indented, you can write several statements on one line, or spread a single statement over several lines.
  You must separate words within a statement with at least one space. The system also interprets the end of line marker as a space.
  The program fragment
  PROGRAM TEST.
  WRITE 'This is a statement'.
  could also be written as follows:
  PROGRAM TEST. WRITE 'This is a statement'.
  or as follows:
  PROGRAM
  TEST.
  WRITE
  'This is a statement'.
  Use this free formatting to make your programs easier to understand.
  Special Case: Text Literals
  Text literals are sequences of alphanumeric characters in the program code that are enclosed in quotation marks. If a text literal in an ABAP statement extends across more than one line, the following difficulties can occur:
  All spaces between the quotation marks are interpreted as belonging to the text literal. Letters in text literals in a line that is not concluded with quotation marks are interpreted by the editor as uppercase. If you want to enter text literals that do not fit into a single line, you can use the ‘&’ character to combine a succession of text literals into a single one.
  The program fragment
  PROGRAM TEST.
  WRITE 'This
  is
  a statement'.
  inserts all spaces between the quotation marks into the literal, and converts the letters to uppercase.
  This program fragment
  PROGRAM TEST.
  WRITE 'This' &
  ' is ' &
  'a statement'.
  combines three text literals into one.
  Chained Statements
  The ABAP programming language allows you to concatenate consecutive statements with an identical first part into a chain statement.
  To concatenate a sequence of separate statements, write the identical part only once and place a colon ( after it. After the colon, write the remaining parts of the individual statements, separating them with commas. Ensure that you place a period (.) after the last part to inform the system where the chain ends.
  Statement sequence:
  WRITE SPFLI-CITYFROM.
  WRITE SPFLI-CITYTO.
  WRITE SPFLI-AIRPTO.
  Chain statement:
  WRITE: SPFLI-CITYFROM, SPFLI-CITYTO, SPFLI-AIRPTO.
  In the chain, a colon separates the beginning of the statement from the variable parts. After the colon or commas, you can insert any number of spaces.
  You could, for example, write the same statement like this:
  WRITE: SPFLI-CITYFROM,
  SPFLI-CITYTO,
  SPFLI-AIRPTO.
  In a chain statement, the first part (before the colon) is not limited to the keyword of the statements.
  Statement sequence:
  SUM = SUM + 1.
  SUM = SUM + 2.
  SUM = SUM + 3.
  SUM = SUM + 4.
  Chain statement:
  SUM = SUM + : 1, 2, 3, 4.
  Comments
  Comments are texts that you can write between the statements of your ABAP program to explain their purpose to a reader. Comments are distinguished by the preceding signs * (at the beginning of a line) and " (at any position in a line). If you want the entire line to be a comment, enter an asterisk (*) at the beginning of the line. The system then ignores the entire line when it generates the program. If you want part of a line to be a comment, enter a double quotation mark (") before the comment. The system interprets comments indicated by double quotation marks as spaces.
  PROGRAM SAPMTEST *
  WRITTEN BY KARL BYTE, 06/27/1995 *
  LAST CHANGED BY RITA DIGIT, 10/01/1995 *
  TASK: DEMONSTRATION *
  PROGRAM SAPMTEST.
  DECLARATIONS *
  DATA: FLAG " GLOBAL FLAG
  NUMBER TYPE I " COUNTER
  PROCESSING BLOCKS *
  Advantages of ABAP over Contemporary languages
  ABAP OBJECTS
  Object orientation in ABAP is an extension of the ABAP language that makes available the advantages of object-oriented programming, such as encapsulation, interfaces, and inheritance. This helps to simplify applications and make them more controllable.
  ABAP Objects is fully compatible with the existing language, so you can use existing statements and modularization units in programs that use ABAP Objects, and can also use ABAP Objects in existing ABAP programs.
  ABAP Statements – an Overview
  The first element of an ABAP statement is the ABAP keyword. This determines the category of the statement. The different statement categories are as follows:
  Declarative Statements
  These statements define data types or declare data objects which are used by the other statements in a program or routine. The collected declarative statements in a program or routine make up its declaration part.
  Examples of declarative keywords:
  TYPES, DATA, TABLES
  Modularization Statements
  These statements define the processing blocks in an ABAP program.
  The modularization keywords can be further divided into:
  · Defining keywords
  You use statements containing these keywords to define subroutines, function modules, dialog modules and methods. You conclude these processing blocks using the END statements.
  Examples of definitive keywords:
  METHOD ... ENDMETHOD, FUNCTION ... ENDFUNCTION, MODULE ... ENDMODULE.
  · Event keywords
  You use statements containing these keywords to define event blocks. There are no special statements to conclude processing blocks - they end when the next processing block is introduced.
  Examples of event key words:
  AT SELECTION SCREEN, START-OF-SELECTION, AT USER-COMMAND
  Control Statements
  You use these statements to control the flow of an ABAP program within a processing block according to certain conditions.
  Examples of control keywords:
  IF, WHILE, CASE
  Call Statements
  You use these statements to call processing blocks that you have already defined using modularization statements. The blocks you call can either be in the same ABAP program or in a different program.
  Examples of call keywords:
  CALL METHOD, CALL TRANSACTION, SUBMIT, LEAVE TO
  Operational Statements These keywords process the data that you have defined using declarative statements.
  Examples of operational keywords:
  MOVE, ADD
  Unique Concept of Internal Table in ABAP
  Internal tables provide a means of taking data from a fixed structure and storing it in working memory in ABAP. The data is stored line by line in memory, and each line has the same structure. In ABAP, internal tables fulfill the function of arrays. Since they are dynamic data objects, they save the programmer the task of dynamic memory management in his or her programs. You should use internal tables whenever you want to process a dataset with a fixed structure within a program. A particularly important use for internal tables is for storing and formatting data from a database table within a program. They are also a good way of including very complicated data structures in an ABAP program.
  Like all elements in the ABAP type concept, internal tables can exist both as data types and as data objects A data type is the abstract description of an internal table, either in a program or centrally in the ABAP Dictionary, that you use to create a concrete data object. The data type is also an attribute of an existing data object.
  Internal Tables as Data Types
  Internal tables and structures are the two structured data types in ABAP. The data type of an internal table is fully specified by its line type, key, and table type.
  Line type
  The line type of an internal table can be any data type. The data type of an internal table is normally a structure. Each component of the structure is a column in the internal table. However, the line type may also be elementary or another internal table.
  Key
  The key identifies table rows. There are two kinds of key for internal tables - the standard key and a user-defined key. You can specify whether the key should be UNIQUE or NON-UNIQUE. Internal tables with a unique key cannot contain duplicate entries. The uniqueness depends on the table access method.
  If a table has a structured line type, its default key consists of all of its non-numerical columns that are not references or themselves internal tables. If a table has an elementary line type, the default key is the entire line. The default key of an internal table whose line type is an internal table, the default key is empty.
  The user-defined key can contain any columns of the internal table that are not references or themselves internal tables. Internal tables with a user-defined key are called key tables. When you define the key, the sequence of the key fields is significant. You should remember this, for example, if you intend to sort the table according to the key.
  Table type
  The table type determines how ABAP will access individual table entries. Internal tables can be divided into three types:
  Standard tables have an internal linear index. From a particular size upwards, the indexes of internal tables are administered as trees. In this case, the index administration overhead increases in logarithmic and not linear relation to the number of lines. The system can access records either by using the table index or the key. The response time for key access is proportional to the number of entries in the table. The key of a standard table is always non-unique. You cannot specify a unique key. This means that standard tables can always be filled very quickly, since the system does not have to check whether there are already existing entries.
  Sorted tables are always saved sorted by the key. They also have an internal index. The system can access records either by using the table index or the key. The response time for key access is logarithmically proportional to the number of table entries, since the system uses a binary search. The key of a sorted table can be either unique or non-unique. When you define the table, you must specify whether the key is to be unique or not. Standard tables and sorted tables are known generically as index tables.
  Hashed tables have no linear index. You can only access a hashed table using its key. The response time is independent of the number of table entries, and is constant, since the system access the table entries using a hash algorithm. The key of a hashed table must be unique. When you define the table, you must specify the key as UNIQUE.
  Generic Internal Tables
  Unlike other local data types in programs, you do not have to specify the data type of an internal table fully. Instead, you can specify a generic construction, that is, the key or key and line type of an internal table data type may remain unspecified. You can use generic internal tables to specify the types of field symbols and the interface parameters of procedures . You cannot use them to declare data objects.
  Internal Tables as Dynamic Data Objects
  Data objects that are defined either with the data type of an internal table, or directly as an internal table, are always fully defined in respect of their line type, key and access method. However, the number of lines is not fixed. Thus internal tables are dynamic data objects, since they can contain any number of lines of a particular type. The only restriction on the number of lines an internal table may contain are the limits of your system installation. The maximum memory that can be occupied by an internal table (including its internal administration) is 2 gigabytes. A more realistic figure is up to 500 megabytes. An additional restriction for hashed tables is that they may not contain more than 2 million entries. The line types of internal tables can be any ABAP data types - elementary, structured, or internal tables. The individual lines of an internal table are called table lines or table entries. Each component of a structured line is called a column in the internal table.
  Choosing a Table Type
  The table type (and particularly the access method) that you will use depends on how the typical internal table operations will be most frequently executed.
  Standard tables
  This is the most appropriate type if you are going to address the individual table entries using the index. Index access is the quickest possible access. You should fill a standard table by appending lines (ABAP APPEND statement), and read, modify and delete entries by specifying the index (INDEX option with the relevant ABAP command). The access time for a standard table increases in a linear relationship with the number of table entries. If you need key access, standard tables are particularly useful if you can fill and process the table in separate steps. For example, you could fill the table by appending entries, and then sort it. If you use the binary search option with key access, the response time is logarithmically proportional to the number of table entries.
  Sorted tables
  This is the most appropriate type if you need a table which is sorted as you fill it. You fill sorted tables using the INSERT statement. Entries are inserted according to the sort sequence defined through the table key. Any illegal entries are recognized as soon as you try to add them to the table. The response time for key access is logarithmically proportional to the number of table entries, since the system always uses a binary search. Sorted tables are particularly useful for partially sequential processing in a LOOP if you specify the beginning of the table key in the WHERE condition.
  Hashed tables
  This is the most appropriate type for any table where the main operation is key access. You cannot access a hashed table using its index. The response time for key access remains constant, regardless of the number of table entries. Like database tables, hashed tables always have a unique key. Hashed tables are useful if you want to construct and use an internal table which resembles a database table or for processing large amounts of data.
  Advanced Topics
  Batch Input: Concepts
  Processing Sessions
  The above figure shows how a batch input session works.A batch input session is a set of one or more calls to transactions along with the data to be processed by the transactions. The system normally executes the transactions in a session non-interactively, allowing rapid entry of bulk data into an R/3 System.
  A session records transactions and data in a special format that can be interpreted by the R/3 System. When the System reads a session, it uses the data in the session to simulate on-line entry of transactions and data. The System can call transactions and enter data using most of the facilities that are available to interactive users.
  For example, the data that a session enters into transaction screens is subject to the same consistency checking as in normal interactive operation. Further, batch input sessions are subject to the user-based authorization checking that is performed by the system.
  Advantages of ABAP over Contemporary languages
  ABAP Objects offers a number of advantages, even if you want to continue using procedural programming. If you want to use new ABAP features, you have to use object-oriented interfaces anyway.
  Sharing Data: With ABAP shared objects, you can aggregate data once at a central location and the different users and programs can then access this data without the need for copying.
  Exception Handling: With the class-based exception concept of ABAP, you can define a special control flow for a specific error situation and provide the user with information about the error.
  Developing Persistency: For permanent storage of data in ABAP, you use relational database tables by means of database-independent Open SQL, which is integrated in ABAP. However, you can also store selected objects transparently or access the integrated database or other databases using proprietary SQL.
  Connectivity and Interoperability: The Exchange Infrastructure and Web services are the means by which developers can implement a service-oriented architecture. With Web services, you can provide and consume services independently of implementation or protocol. Furthermore, you can do so within NetWeaver and in the communication with other systems. With the features of the Exchange Infrastructure, you can enable, manage, and adapt integration scenarios between systems.
  Making Enhancements: With the Enhancement Framework, you can enhance programs, function modules, and global classes without modification as well as replace existing code. The Switch Framework enables you activate only specific development objects or enhancements in a system.
  Considerable Aspects
  It follows a list of aspects to be considered during development. The list of course is not complete.
  Dynpro persistence
  When implementing dynpros one has to care for himself to read out and persist the necessary fields. Recently it happened to me that I forgot to include a field into the UPDATE-clause which is an error not so easy to uncover if you have other problems to be solved in the same package. Here, tool-support or built-in mechanisms would help.
  The developer could help himself out by creating something like a document containing a cookbook or guide in which parts of a dynpro logic one has to care about persistence. With that at hand, it would be quite easy finding those bugs in short time. Maybe a report scanning for the definition of the dynpro fields to be persisted could scan the code automatically, too.
  Memory Cache
  It should be common-sense that avoiding select-statements onto the database helps reducing the server load. For that the programmer either can resort to function modules if available. This maybe is the case for important tables. Or the programmer needs to implement his own logic using internal tables. Here, the standard software package could provide the developer with a tool or a mechanism auto-generating memory cached tables resp. function modules implementing this.
  Sometimes buffering of database tables could be used, if applicable. But that would require an effort in customizing the system and could drain down system performance overall, especially if a table is involved that has a central role.
  Interfaces
  It should be noticed that some function modules available have an incomplete interface. That means, the interface does not include all parameters evaluated by the logic of the function module. For example, global variables from within the function group could be read out, which cannot be influenced by the general caller. Or memory parameters are used internally to feed the logic with further information.
  One workaround here would be copying the relevant parts of the logic to a newly created function module and then adapt it to the own context. This sometimes is possible, maybe if the copied code is not too lengthy and only a few or no calls to other logic is part of it.
  A modification of the SAP code could be considered, if the modification itself is unavoidable (or another solution would be not justifiable by estimated effort to spend on it) and if the location of the modification seems quite safe against future upgrades or hot fixes. The latter is something that could be evaluated by contacting the SAP hotline or working with OSS message (searching thru existing one, perhaps open a new one).
  Example
  'From SAP NetWeaver:'
  set an exclusive lock at level object-type & object-id
  IF NOT lf_bapi_error = true.
  IF ( NOT istourhd-doc_type IS INITIAL ) AND
  ( NOT istourhd-doc_id IS INITIAL )
  CALL FUNCTION 'ENQUEUE_/DSD/E_HH_RAREF'
  EXPORTING
  obj_typ = istourhd-doc_type
  obj_id = istourhd-doc_id
  EXCEPTIONS
  foreign_lock = 1
  system_failure = 2
  OTHERS = 3.
  IF sy-subrc <> 0.
  terminate processing...
  lf_bapi_error = true.—
  ...and add message to return table
  PERFORM set_msg_to_bapiret2
  USING sy-msgid gc_abort sy-msgno
  sy-msgv1 sy-msgv2 sy-msgv3 sy-msgv4
  gc_istourhd gc_enqueue_refdoc space
  CHANGING lt_return.
  ENDIF.
  ENDIF.
  ENDIF. " bapi error
  Example Report(Type - ALV(Advanced List Viewer))
  REPORT Z_ALV_SIMPLE_EXAMPLE_WITH_ITAB .
  *Simple example to use ALV and to define the ALV data in an internal
  *table
  *data definition
  tables:
  marav. "Table MARA and table MAKT
  Data to be displayed in ALV
  Using the following syntax, REUSE_ALV_FIELDCATALOG_MERGE can auto-
  matically determine the fieldstructure from this source program
  Data:
  begin of imat occurs 100,
  matnr like marav-matnr, "Material number
  maktx like marav-maktx, "Material short text
  matkl like marav-matkl, "Material group (so you can test to make
  " intermediate sums)
  ntgew like marav-ntgew, "Net weight, numeric field (so you can test to
  "make sums)
  gewei like marav-gewei, "weight unit (just to be complete)
  end of imat.
  Other data needed
  field to store report name
  data i_repid like sy-repid.
  field to check table length
  data i_lines like sy-tabix.
  Data for ALV display
  TYPE-POOLS: SLIS.
  data int_fcat type SLIS_T_FIELDCAT_ALV.
  select-options:
  s_matnr for marav-matnr matchcode object MAT1.
  start-of-selection.
  read data into table imat
  select * from marav
  into corresponding fields of table imat
  where
  matnr in s_matnr.
  Check if material was found
  clear i_lines.
  describe table imat lines i_lines.
  if i_lines lt 1.
  Using hardcoded write here for easy upload
  write: /
  'No materials found.'.
  exit.
  endif.
  end-of-selection.
  To use ALV, we need a DDIC-structure or a thing called Fieldcatalogue.
  The fieldcatalouge can be generated by FUNCTION
  'REUSE_ALV_FIELDCATALOG_MERGE' from an internal table from any
  report source, including this report.
  Store report name
  i_repid = sy-repid.
  Create Fieldcatalogue from internal table
  CALL FUNCTION 'REUSE_ALV_FIELDCATALOG_MERGE'
  EXPORTING
  I_PROGRAM_NAME = i_repid
  I_INTERNAL_TABNAME = 'IMAT' "capital letters!
  I_INCLNAME = i_repid
  CHANGING
  CT_FIELDCAT = int_fcat
  EXCEPTIONS
  INCONSISTENT_INTERFACE = 1
  PROGRAM_ERROR = 2
  OTHERS = 3.
  *explanations:
  I_PROGRAM_NAME is the program which calls this function
  I_INTERNAL_TABNAME is the name of the internal table which you want
  to display in ALV
  I_INCLNAME is the ABAP-source where the internal table is defined
  (DATA....)
  CT_FIELDCAT contains the Fieldcatalouge that we need later for
  ALV display
  IF SY-SUBRC <> 0.
  write: /
  'Returncode',
  sy-subrc,
  'from FUNCTION REUSE_ALV_FIELDCATALOG_MERGE'.
  ENDIF.
  *This was the fieldcatlogue
  Call for ALV list display
  CALL FUNCTION 'REUSE_ALV_LIST_DISPLAY'
  EXPORTING
  I_CALLBACK_PROGRAM = i_repid
  IT_FIELDCAT = int_fcat
  TABLES
  T_OUTTAB = imat
  EXCEPTIONS
  PROGRAM_ERROR = 1
  OTHERS = 2.
  *explanations:
  I_CALLBACK_PROGRAM is the program which calls this function
  IT_FIELDCAT (just made by REUSE_ALV_FIELDCATALOG_MERGE) contains
  now the data definition needed for display
  I_SAVE allows the user to save his own layouts
  T_OUTTAB contains the data to be displayed in ALV
  IF SY-SUBRC <> 0.
  write: /
  'Returncode',
  sy-subrc,
  'from FUNCTION REUSE_ALV_LIST_DISPLAY'.
  ENDIF.
  OOPs ABAP uses Classes and Interfaces which uses Methods and events.
  If you have Java skills it is advantage for you.
  There are Local classes as well as Global Classes.
  Local classes we can work in SE38 straight away.
  But mostly it is better to use the Global classes.
  Global Classes or Interfaces are to be created in SE24.
  SAP already given some predefined classes and Interfaces.
  This OOPS concepts very useful for writing BADI's also.
  So first create a class in SE 24.
  Define attributes, Methods for that class.
  Define parameters for that Method.
  You can define event handlers also to handle the messages.
  After creation in each method write the code.
  Methods are similar to ABAP PERFORM -FORM statements.
  After the creation of CLass and methods come to SE38 and create the program.
  In the program create a object type ref to that class and with the help of that Object call the methods of that Class and display the data.
  Regards
  Anji

• Gereral differences between 4.7 and ECC 6.0 from FI/CO view

  Hi Guys
  Can any one tell me key differences between 4.7 and ECC 6.0 from FI/CO view.
  In interview what i must tell?
  Thank you.

  Please visit the following links:
  [http://service.sap.com/erp]
  [http://solutionbrowser.erp.sap.fmpmedia.com/ (Functional prespective)]
  [http://service.sap.com/instguides] --> mySAP Business Suite Applications --> mySAP ERP --> mySAP ERP 2005 --> Upgrade
  [http://help.sap.com/printdocu/core/Print46c/en/data/pdf/LOVC/LOVC.pdf]
  For Functionality Differences pls refer to the below site -
  [http://solutionbrowser.erp.sap.fmpmedia.com/]
  After opening the site, please select the Source Release Version which is 4.6 b Then Select the Target Release Version which is "mySAP ERP 2005" or ECC 6.0
  Select the Solution Area like Financials, Human Capital Management, Sales....
  Select module like MM, PP, SD, QM.....
  Click on Search
  Then it displays the Release Version and the Delta Functionality. which can be downloaded to a word document if required.
  and also check the release notes of ECC 6.0 in service.sap.com.
  Regards,
  Ajit

• EXACT DIFFERENCE BETWEEN  FULL LOAD AND REPAIRFULL LOAD?

  HI Champ,
  Can anyone explain me the exact difference between  full load and Repairfull load?Give e some senario where we can go for this?Please.....
  10zin

  Hi,
  Full repair can be said as a Full with selections. But the main use or advantage of Full repair load is that it wont affect delta loads in the system. If you load a full to a target with deltas running you again will have to initialize them for deltas to continue. But if you do full repair it wont affect deltas.
  This is normally done we when we lose some data or there is data mismatch between source system and BW.
  Check the OSS Note 739863 'Repairing data in BW' for all the details
  Symptom
  Some data is incorrect or missing in the PSA table or in the ODS object (Enterprise Data Warehouse layer).
  There may be a number of reasons for this problem: Errors in the relevant application, errors in the user exit, errors in the DeltaQueue, handling errors in the customers posting procedure (for example, a change in the extract structure during production operation if the DeltaQueue was not yet empty; postings before the Delta Init was completed, and so on), extractor errors, unplanned system terminations in BW and in R/3, and so on.
  Solution
  Read this note in full BEFORE you start actions that may repair your data in BW. Contact SAP Support for help with troubleshooting before you start to repair data.
  BW offers you the option of a full upload in the form of a repair request (as of BW 3.0B). If you want to use this function, we recommend that you use the ODS object layer.
  Note that you should only use this procedure if you have a small number of incorrect or missing records. Otherwise, we always recommend a reinitialization (possibly after a previous selective deletion, followed by a restriction of the Delta-Init selection to exclude areas that were not changed in the meantime).
  1. Repair request: Definition
  If you flag a request as a repair request with full update as the update mode, it can be updated to all data targets, even if these already contain data from delta initialization runs for this DataSource/source system combination. This means that a repair request can be updated into all ODS objects at any time without a check being performed. The system supports loading by repair request into an ODS object without a check being performed for overlapping data or for the sequence of the requests. This action may therefore result in duplicate data and must thus be prepared very carefully.
  The repair request (of the "Full Upload" type) can be loaded into the same ODS object in which the 'normal' delta requests run. You will find this request under the "Repair Request" option in the InfoPackage (Maintenance) menu.
  2. Prerequisites for using the "Repair Request" function
  2.1. Troubleshooting
  Before you start the repair action, you should carry out a thorough analysis of the possible cause of the error to make sure that the error cannot recur when you execute the repair action. For example, if a key figure has already been updated incorrectly in the OLTP system, it will not change after a reload into BW. Use transaction RSA3 (Extractor Checker) in the source system for help with troubleshooting. Another possible source of the problem may be your user exit. To ensure that the user exit is correct, first load a user exit with a Probe-Full request into the PSA table and check whether the data is correct. If it is not correct: Search for the error in the exit user. If you do not find it, we recommend that you deactivate the user exit for testing purposes and request a new Full Upload. It If the data arrives correctly, it is highly probable that the error is indeed in the user exit.
  We always recommend that you load the data into the PSA table in the first step and check the result there.
  2.2. Analyze the effects on the downstream targets
  Before you start the Repair request into the ODS object, make sure that the incorrect data records are selectively deleted from the ODS object. However, before you decide on selective deletion, you should read the Info Help for the "Selective Deletion" function, which you can access by pressing the extra button on the relevant dialog box. The activation queue and the ChangeLog remain unchanged during the selective deletion of the data from the ODS object, which means that the incorrect data is still in the change log afterwards. After the selective deletion, you therefore must not reconstruct the ODS object if it is reconstructed from the ChangeLog. (Reconstruction is usually from the PSA table but, if the data source is the ODS object itself, the ODS object is reconstructed from its ChangeLog). You MUST read the recommendations and warnings about this (press the "Info" button).
  You MUST also take into account the fact that the delta for the downstream data targets is created from the changelog. If you perform selective deletion and then reload data into the deleted area, this may result in data inconsistencies in the downstream data targets.
  If you only use MOVE and do not use ADD for updates in the ODS object, selective deletion may not be required in some cases (for example, if incorrect records only have to be changed, rather than deleted). In this case, the DataMart delta also remains intact.
  2.3. Analysis of the selections
  You must be very precise when you perform selective deletion: Some applications do not provide the option of selecting individual documents for the load process. Therefore, you must first ensure that you can load the same range of documents into BW as you would delete from the ODS object. This note provides some application-specific recommendations to help you "repair" the incorrect data records.
  If you updated the data from the ODS object into the InfoCube, you can also delete it there using the "Selective deletion" function. However, if it is compressed at document level there and deletion is no longer possible, you must delete the InfoCube content and fill the data in the ODS object again after repair.
  You can only perform this action after a thorough analysis of all effects of selective data deletion. We naturally recommend that you test this first in the test system.
  The procedure generally applies for all SAP applications/extractors. The application determines the selections. For example, if you cannot use the document number for selection but you can select documents for an entire period, then you are forced to delete and then update documents for the entire period in the data target. Therefore, it is important to look first at the selections in the InfoPackage exactly before you delete data from the data target.
  Some applications have additional special features:
  Logistics cockpit: As preparation for the repair request, delete the SetUp table (if you have not already done so) and fill it selectively with concrete document numbers (or other possible groups of documents determined by the selection). Execute the Repair request.
  Caution: You can currently use the transactions that fill SetUp tables with reconstruction data to select individual documents or entire ranges of documents (at present, it is not possible to select several individual documents if they are not numbered in sequence).
  FI: The Repair request for the Full Upload is not required here. The following efficient alternatives are provided: In the FI area, you can select documents that must be reloaded into BW again, make a small change to them (for example, insert a period into the assignment text) and save them -> as a result, the document is placed in the delta queue again and the previously loaded document under the same number in the BW ODS object is overwritten. FI also has an option for sending the documents selectively from the OLTP system to the BW system using correction programs (see note 616331).
  3. Repair request execution
  How do you proceed if you want to load a repair request into the data target? Go to the maintenance screen of the InfoPackage (Scheduler), set the type of data upload to "Full", and select the "Scheduler" option in the menu -> Full Request Repair -> Flag request as repair request -> Confirm. Update the data into the PSA and then check that it is correct. If the data is correct, continue to update into the data targets."
  Refer.
  Repair full request
  Re: Repair full request
  Steps to perform repair full request
  full repair request
  repair full request
  Re: Repair Full Request
  Thanks,
  JituK

• Difference between SRM 7 and SRM 5 Workflow

  Hello all
  what is the difference between SRM 7 and SRM 5 Workflow.
  Reagrds
  Marco

  Dear Prakash,
  Please visit the following links:
  http://service.sap.com/erp
  http://solutionbrowser.erp.sap.fmpmedia.com/ (Functional prespective)
  http://service.sap.com/instguides --> mySAP Business Suite Applications --> mySAP ERP --> mySAP ERP 2005 --> Upgrade
  http://help.sap.com/printdocu/core/Print46c/en/data/pdf/LOVC/LOVC.pdf
  For Functionality Differences pls refer to the below site -
  http://solutionbrowser.erp.sap.fmpmedia.com/
  After opening the site, please select the Source Release Version which is 4.6 b Then Select the Target Release Version which is "mySAP ERP 2005" or ECC 6.0
  Select the Solution Area like Financials, Human Capital Management, Sales....
  Select module like MM, PP, SD, QM.....
  Click on Search
  Then it displays the Release Version and the Delta Functionality. which can be downloaded to a word document if required.
  and also check the release notes of ECC 6.0 in service.sap.com.
  Hope this helps you.
  Do award points if you found them useful.
  Regards,
  Rakesh
  P.S. you can send me a mail at my mail id [email protected] for any specific details

• Getting difference between GMT time and Local time

  Folks,
  I am trying to get difference between gmt time and local time for Korea time zone.
  which should be 9 hours.
  Instead of 9, I am getting 15 hours diff.
  What am I doing wrong?
  Here's what I did to test it:
  First I set the system (Windows XP) time zone to Soul (Korea GMT+9hours) time zone.
  Then I ran the following program, and I got 15 hour diff, not 9.
  Thank you in advance!
  import java.util.*;
  public class Using_GregorianCalendar
       public static void main(String args[])
            Using_GregorianCalendar ugc = new Using_GregorianCalendar();
            ugc.getTimeDiff();
       public void getTimeDiff()
            Calendar cal = new GregorianCalendar(TimeZone.getTimeZone("GMT"));
            Calendar cal1 = new GregorianCalendar(cal.get(Calendar.YEAR),
                                         cal.get(Calendar.MONTH),
                                         cal.get(Calendar.DATE),
                                         cal.get(Calendar.HOUR_OF_DAY),
                                         cal.get(Calendar.MINUTE),
                                                    cal.get(Calendar.SECOND));
          int gmtHour          =  cal.get(Calendar.HOUR); //(Calendar.HOUR_OF_DAY);
          int gmtHourOfDay =  cal.get(Calendar.HOUR_OF_DAY);
          int gmtMonth        =  cal.get(Calendar.MONTH);
          int gmtYear          =  cal.get(Calendar.YEAR);
          int gmtMinute       =  cal.get(Calendar.MINUTE);
          int gmtSecond     =   cal.get(Calendar.SECOND);
          int gmtDate         = cal.get(Calendar.DATE);
          Calendar localCal  = Calendar.getInstance();
          int localHourOfDay = localCal.get(Calendar.HOUR_OF_DAY);
          int timeDiff = (localHourOfDay - gmtHourOfDay);
            //Korea time is GMT + 9 hours so I should get a difference of 9
            //why am I getting difference of 15?
               System.out.println("************** in getTimeDiff() **********************");
            System.out.println("gmtDate: "+gmtDate);
            System.out.println("gmtHour: "+gmtHour);
            System.out.println("gmtHourOfDay: "+gmtHourOfDay);
            System.out.println("localHourOfDay: "+localHourOfDay);
            System.out.println("timeDiff: "+timeDiff);
            System.out.println("**********************************************************");
       }//getTimeDiff()
  }//class Using_GregorianCalendar
  /*              here's the output of this program:
       ************** in getTimeInGMT() **********************
       gmtDate: 14
       gmtHour: 6
       gmtHourOfDay: 18
       localHourOfDay: 3
       timeDiff: -15
  */

  DrClap wrote:
  sabre150 wrote:
  Nearly correct since the Daylight saving may or may not be in effect which does depend on the date...I would simplify that to this:
  TimeZone korea = TimeZone.getTimeZone("Asia/Seoul");
  long delta = korea.getOffset(new Date().getTime());
  System.out.println(delta / (1000.0 * 60 * 60));That's assuming that the OP really meant UTC when he/she said "GMT". Most people don't realize there's a distinction and that Java's timezones are all based relative to UTC.I suspect you are right in assuming that the OP want UTC and not GMT. I figured it was better to illustrate that the method can be used for getting the time difference between any two TimeZones.

• Difference between 4.7 and ECC 5/6

  Hi Friends,
  I am ABAP developer and would like to know the differences between 4.7 and ECC 5.0 and ECC 6.0 from a techincal perspective. I appreciate if you differentiate between each of them  or 4.7 and ECC 5.0.
  Regards
  Prakash

  Dear Prakash,
  Please visit the following links:
  http://service.sap.com/erp
  http://solutionbrowser.erp.sap.fmpmedia.com/ (Functional prespective)
  http://service.sap.com/instguides --> mySAP Business Suite Applications --> mySAP ERP --> mySAP ERP 2005 --> Upgrade
  http://help.sap.com/printdocu/core/Print46c/en/data/pdf/LOVC/LOVC.pdf
  For Functionality Differences pls refer to the below site -
  http://solutionbrowser.erp.sap.fmpmedia.com/
  After opening the site, please select the Source Release Version which is 4.6 b Then Select the Target Release Version which is "mySAP ERP 2005" or ECC 6.0
  Select the Solution Area like Financials, Human Capital Management, Sales....
  Select module like MM, PP, SD, QM.....
  Click on Search
  Then it displays the Release Version and the Delta Functionality. which can be downloaded to a word document if required.
  and also check the release notes of ECC 6.0 in service.sap.com.
  Hope this helps you.
  Do award points if you found them useful.
  Regards,
  Rakesh
  P.S. you can send me a mail at my mail id [email protected] for any specific details

• Difference between 4.7 and ECC6

  Hi
  Could any one explain me the difference between 4.7 and ECC6
  Regards
  Uday

  Hi,
  Please visit the following links:
  http://service.sap.com/erp
  http://solutionbrowser.erp.sap.fmpmedia.com/ (Functional prespective)
  http://service.sap.com/instguides --> mySAP Business Suite Applications --> mySAP ERP --> mySAP ERP 2005 --> Upgrade
  http://help.sap.com/printdocu/core/Print46c/en/data/pdf/LOVC/LOVC.pdf
  For Functionality Differences pls refer to the below site -
  http://solutionbrowser.erp.sap.fmpmedia.com/
  After opening the site, please select the Source Release Version which is 4.6 b Then Select the Target Release Version which is "mySAP ERP 2005" or ECC 6.0
  Select the Solution Area like Financials, Human Capital Management, Sales....
  Select module like MM, PP, SD, QM.....
  Click on Search
  Then it displays the Release Version and the Delta Functionality. which can be downloaded to a word document if required.
  and also check the release notes of ECC 6.0 in service.sap.com.
  Hope this helps you.
  Regards,
  Rakesh

• Difference between 4.6 and ECC 6.0

  Can anybody tell me what is the difference between 4.6 and ECC 6.0 related to SD Module.

  Hi Sunil,
  .  Please visit the following links:
  http://service.sap.com/erp
  http://solutionbrowser.erp.sap.fmpmedia.com/ (Functional perspective)
  http://service.sap.com/instguides --> mySAP Business Suite Applications --> mySAP ERP --> mySAP ERP 2005 --> Upgrade
  http://help.sap.com/printdocu/core/Print46c/en/data/pdf/LOVC/LOVC.pdf
  For Functionality Differences pls refer to the below site -
  http://solutionbrowser.erp.sap.fmpmedia.com/
  After opening the site, please select the Source Release Version which is 4.6 b Then Select the Target Release Version which is "mySAP ERP 2005" or ECC 6.0
  Select the Solution Area like Financials, Human Capital Management, Sales....
  Select module like MM, PP, SD, and QM.....
  Click on Search
  then it displays the Release Version and the Delta Functionality. Which can be downloaded to a word document if required.
  And also check the release notes of ECC 6.0 in service.sap.com.
  A2. When you are upgrading from 4.6C to ECC6
  Nothing major, follow the same process you'd follow if you were updating PI service packs in R/3 or enhancing data sources. Empty queues in RSA7 and lbwq. Also empty setup tables through lbwg as the upgrade doesn't like it if these tables contain data. This is all on the R/3 side (although you empty RSA7 by running each delta TWICE in BW).
  To transfer queues from lbwq to rsa7, execute jobs through LO cockpit (lbwe).
  Some of your data sources could also be using sm13 instead of lbwq, so do check it out as well.
  For installing ECC 6.0 you required a solution manager key. With out solution manager key you cannot install ECC6.0.
  For ECC 6.0 is called net weaver component here you have ABAP+JAVA stack.
  ECC6.0 supports UNCODE.
  For installing 4.6 you don't require solution manager key. It only having ABAP stack.
  4.6C supports NONUNICODE.
  Major difference is ECC6 is netwear product having WASJAVA+ABAP
  secondly support unicode apart from this we have other diff. you can get form master guide from service.sap.com/instguides.
  Please go through the link that is shown here and if there is any doubts then feel free to ask.
  A3. Major difference is ECC6 is net weaver  product having WASJAVA+ABAP
  secondly support Unicode apart from this we have other diff. you can get from master guide from service.sap.com/instguides
  For installing ECC 6.0 you required a solution manager key. With out solution manager key you cannot install ECC6.0.
  For ECC 6.0 is called net weaver component here you have ABAP+JAVA stack.
  ECC6.0 supports UNCODE.
  For installing 4.6 you don't required solution manager key. It only having ABAP stack.
  4.6C supports NONUNICODE.
  A4. Refer sdn thread and make a small search where u can find lot of information Reg this
  olution Browser would give the differences (Features):
  http://solutionbrowser.erp.sap.fmpmedia.com/ Give source and target versions.
  Release Info:
  ECC 6.0:
  http://help.sap.com/saphelp_erp2005/helpdata/en/43/68805bb88f297ee10000000a422035/frameset.htm
  Refer below and search for posts on this topic on sdn
  There are so many differences between the version in different objects
  I
  These are the some of the settings that are differed in the two versions and in that two objects
  Please visit the following links:
  http://service.sap.com/erp
  http://solutionbrowser.erp.sap.fmpmedia.com/ (Functional prespective)
  http://service.sap.com/instguides --> mySAP Business Suite Applications --> mySAP ERP --> mySAP ERP 2005 --> Upgrade
  http://help.sap.com/printdocu/core/Print46c/en/data/pdf/LOVC/LOVC.pdf
  For Functionality Differences pls refer to the below site -
  http://solutionbrowser.erp.sap.fmpmedia.com/
  Upgrade from 4.6c to 6.0 ECC
  upgrade from 4.7 to ecc 6.0
  Please Reward If Really Helpful,
  Thanks and Regards,
  Sateesh.Kandula