Distribution Routes in CHaRM

Similar Messages

• Charm distribution routes,

  I am in the phase of configuring CHARM on Solman 4.0 with sp level 11. I have done the basic settings like Tms configuration, creating domain links, generationg rfc and smsy configurration and also i checked the configuration by running the transcation /TMWFLOW/CHARMCHK. its showing everything green.
  I also checked the same in solar_project_admin, -- system landscape>change request tab>check consistensy its also displaying the same.
  I dont know what is my next step in this configuration.Could you please anyone suggest me.
  I ahve one more doubt in \n\tmwflow\cmsconf... i have only two tabs that is critical objects as well as sytem change options(in this tab no sytems are assigned)
  no other tabs  like distribution routes,general settings,etc..
  I also seen many threads asked this same question but noone got answered for this. Anyone have idea on this please suggest me.
  Regards
  Vijay

  I dont know what is my next step in this configuration.Could you please anyone suggest me.
  Scenario specific settings in SPRO should give you an idea of what to do.
  I ahve one more doubt in \n\tmwflow\cmsconf... i have only two tabs that is critical objects as well as sytem change options(in this tab no sytems are assigned) no other tabs like distribution routes,general settings,etc..
  It's quite normal that you only got 2 tabs there.
  You need to assign systems to a project (SOLAR_PROJECT_ADMIN) and release the project to ChaRM before any systems appear.
  Re: No system listed in /TMWFLOW/CMSCONFIG
  /cheers

• Regarding the tab Distribution Routes is hided and scheduling button too

  Hi Techies,
  Iam trying to configure the Change Request in Solution Manger 4.0 system while doing so i want to configure in Central Configuration of change management for this what is the tcode available in Solman4.0 and anybody know how to configure the Change request management
  the tab Distribution Routes is hided and scheduling button is also hided in Change Request Management
  solutions rewarded!!
  regards,
  S.Rajeshkumar

  Hi
  I want to access GL item tab account number from MIRO transaction to BADIINVOICE_BADI Method CHANGE_AT_SAVE. I entered the account number in GL account tnumber tab. but parameter TI_RBCO_NEW-BUKRS & TI_RBCO_OLD-BUKRS values are empty inside BADI method.
  Can you suggest me how to find this.
  Regards
  Chandra
  Edited by: princeck on Oct 3, 2011 2:32 PM

• Re:/tmwflow/cmsconf transaction - scheduling and distribution routes hided

  Hi gurus,
  Iam configuring the ChaRM for this i have done the IMG,TMS all the activities but i can t find the systems in the /tmwflow/cmsconf transaction. The distribution button and the sceduling button are hided ,how to enable it !
  solutions awarded for sure!
  regards,
  esr kumar

  Hi,
  Please kindly ensure that the IMG has been configured correctly especially in the perspective for ChaRM;
  SAP Solution Manager
  - Advanced Configuration
     -Scenario-Specific Settings
       -Change Request Management
         -Standard Configuration
           -Transport Management System
  Extended Configuration is for the purpose, if you need to specify
  Critical Transport Objects, or Reproting Service. But before coming to
  this part, the standard configuration has to be completed and working.
  Hope this helps.
  Cheers
  SH

• Sales & Distribution - Route at Schedule Agreement

  Dear all,
  When receiving PO or Schedule Agreement from the customers
  we can pull back the delivery date, as lead-time, using the "Route"
  in Schedule Agreement VA33-Item-Shipping.
  For example, the customer delivery date is 07/21/2008 (monday)
  and when updating VA32-Route=000002 (1-day-lead-time), SAP pulls back
  to sunday(07/20/2008).
  But, how can we check if the date that SAP pulls back is in weekend?

  Hi
  If the weekends are Non Working days in Shipping Point and also Customer Master - Unloading details, then I believe it cannot determine the weekends.
  Thanks,
  Ravi

• ChaRM: transport layer/routes used by ChaRM

  Hi!
  We have very complex trasport system settings and would like to implement ChaRM with parallel usage of transports in non-ChaRM environment.
  We have a lot of transport routes (between DEV:100 and QAS:100) (e.g. SAP, ZDEV, ZFAD, ZGFA, YDAS).
  How can we split the transport routes for ChaRM and transport routes for transports without ChaRM?
  Which transport routes will be used with ChaRM?
  Thank you very much!

  Hi
  as already mentioned in one of my replies to your last thread, ChaRM always (and only) uses the standard transport layer (route) per client.
  This one and all other ones can be used for non-ChaRM transports. This is standard TMS functionality.
  But you have to check if the "ChaRM check" in your project configuration accepts your TMS settings. Maybe the other transport layers/routes make waves. Then you have to change them...
  regards
  Andreas

• Charm: No Domain Controller for SB5

  Hi,
  I configured Charm in solution Manager 4.0, created a satellite system SB5 in smsy and run the batch to get the info to charm. now i have it in /tmwflow/cmsconf but when i synchronize the project in solar_admin_project we get the error No Domain Controller for SB5.
  The STMS is configured correctly in SB5
  The RFC dests are OK also from SMSY i can see the dommain controller without any problem and distribution routes also.
  Any advise
  Thanks
  Ahmed

  Thanks Pascal,
  I was able to fix the problen but adding a domain link between solution manager and satellite systems.
  Ahmed

• Transport of modifications with ChaRM in client "000"?

  Hi,
  I do have a typical logical component DEV:100 -> QAS:100 -> PRD:100.
  For standard customizing and workbech tansports all is working fine.
  Now I have done a modification on a standard SAP object. Therfore the system wants to have a transport for client "000".
  But with standard ChaRM I only user the typical logical component with the standard transport routes for client 100.
  Does anyone have had a similar problem or a solution for that?
  To change the system in the transport does not work, because SolMan does check the ChaRM related transports within a special table.
  The only solution, which is in my mind, is the use of a second logical component for client "000" to do the modifications.
  Thanks for any help.
  Regards,
  Alex

  Agree with you Alex. For defining multiple routes in ChaRM, you need to define different logical components and assign them to the maintenance cycle.
  Rajeev

• ChaRM: usage of ChaRM and none-Charm transport strategy

  Hi ChaRM-TMS Gurus!
  We have the following [SAP system landscape |http://www.file-upload.net/view-1086963/SDN_TMS_Ist_Soll.jpg.html] and would like to use ChaRM approach simultaneously.
  What are the minimal requirements concerning transport layers/routes, which settings should be changed?
  How much and which transport layer/routes does ChaRM need?
  a) 1 any new transport layer/route
  b) standard transport layer, transport layer "SAP" and others
  Should all the standard transport layer/routes from virtual systems to real QAS and PRD systems or can I start as follows:
  1) Leave the current TMS settings unchanged
  2) Activate the extended transport control
  Result: the current setting will be client specific and all the old transport requests will be moved to client specific transport routes
  3) change the transport strategy (from mass transport to single transport)
  3) Define new transport layer
  4) Define  new transport route for SAP objects from DEV to QAS
  and assign the transport layer from 3) (client specific)
  5) Define  new transport route ZXXX from DEV to QAS
  and assign the transport layer from 3) (client specific)
  6) Define the delivery transport route from QAS to PRD (client specific)
  7) activate and distribute the settings
  Thank you very much indeed!
  Thom

  Hi Martin,
  Solmaniacs' assumptions are correct. You can have as many source clients as you want.
  As long as
  - STMS configuration (transport routes, and domain links) are consistent
  - SMSY configuration (logical components are declared properly with assigning the right role types to systems/clients)
  - Project declaration are done correctly (so that from Solman solar_project_admin you can read the STMS as confiured in the distant STMS domain)
  - IMPORTANT: those configuration GO ALONG with each other !! (SMSY should nt contradict STMS for example...)
  The tasklist that is generated for each Solman project will be as follow
  - Node 1: Header Tasks (commun to all systems)
  - Node x: Corresponding to track x declared in Project (each Source System will have his own node with the corresponding track under)
  - Node x+1
  - Node ...
  - Last Node : Tasks for Tasklist closure - checks on scma consistancy and CTS projects closure
  So you'll always have n+2 nodes in your tasklist; n beeing the number of declared source (=dev) systems in project
  For each action launched from change docuemnts like creation of TR, release of TR or Retrofit (as Solmaniac said) you'll have an additional pop-up that will appears letting you choose the system you want to use for the action
  Hope its helpful
  Regards
  Khalil

• Routed access design to support up to 2500 multicast groups

  Hi all,
  I'm doing routed access design with following:
  - Routing protocol is OSPF.
  - 3 layers with: Core/Distribution/Access design.
  - Core: Catalyst 6500E Sup 2T.
  - Distribution: ME 3800X / Catalyst 4500X.
  - Access: ME 3400E.
  We enable PIM from Core to Access layer.
  At the moment, there are around 1000 multicast group in the network.
  Cisco hardware limitation of multicast:
  - Cisco ME 3400E can only support up to 1000 IGMP groups and multicast routes.
  - Cisco ME 3800X can only support up to 2000 IGMP group and multicast routes with Metro IP Services license.
  - Cisco Catalyst 4500X support up to 32K multicast routes.
  - Cisco Catalyst 6500E Sup 2T support up to 128K multicast routes.
  Requirement:
  Design the network to support up to 2500 multicast groups.
  So, are there any fine-tune in the design to meet above requirement?
  Or I have to change access layer switch to higher model? (ex: 4500E)
  Thanks,

  hi there
  replacing the hardware is one option
  but the question here why are you going with routed access layer and in your case you have large Mcast routing table  that going to be everywhere !!
  have you considered using Cat65k or 45K in the distribution in VSS and use L2 from access to distribution
  in this case you need to concern about the distribution routing table size and also VSS simplify the topology and managerially of the network rather than have it with a complicated routing design
  routed access is a good and recommend as well for quicker convergence time and no reliance on STP or HSRP/VRRP timers
  however it could comlicate the routing design !
  while VSS will also eliminate the reliance on HSRP/VRRP and STP with more added simplicity to the topology and design
  so you may go with 45K VSS in the distribution and 65K with VSS in the core as well and in the access using L2 uplinks to the distribution and the uplinks everywhere can use multi-chassis etherchannel MEC, for increased network capacity in terms of bandwidth and quicker convergence time in the case of a link failure as well, Plus you will be able to support the desired Mcast routing table in the distribution and Core !!
  hope this help

• Automatic transport with ChaRM

  Hi!
  We transport currently all transports with u201EIMPORT ALLu201Cmethod and are thinking about the implementation of ChaRM.
  This method (u201CIMPORT ALLu201D) allows us to transport the transports at 10 and 14 ou2019clock automatically from DEV into QAS system
  As we know ChaRM works with SINLGE IMPORT method (CTC=1).
  Questions
  1) Do we have any possibilities for the automatic transport in ChaRM?
  If Yes, how does it work?
  2) Do we have any possibilities for locking of objects and mechanisms to avoid "outrun of transportsu201D?
  Developer 1 works with objects A, B, C, changes the object B and transports them into QAS system.
  Developer 2 works with objects B, G, H, transports the object B into QAS system.
  Now he has the other version of object B, because the object B was changed by developer A.
  Does ChaRM offer some mechanisms to avoid  u201Coutrun of transportsu201D?
  Any helpful information will be very appreciated and awarded with points.
  Thank you very much!

  Hi!
  Thank you very much again.
  The problem is we would like to use non-ChaRM and ChaRM transports simultaneously in same DEV client (e.g. 100). The same applies for QAS system (e.g. client 200).
  We would like to integrate other transport routes into ChaRM.
  Do you think we have possibility to integrate this.
  Please have a look into our system landscape [SAP system landscape |http://www.file-upload.net/view-1086963/SDN_TMS_Ist_Soll.jpg.html].
  Please help to clarify....
  I awarded you point...

• Change Management. Cannot go to the next phase ... And common questions.

  Hi dear colleagues!
  Here there are some unpleasant problems which has arisen during Change Management functions realization...
  1. After approving of Urgent Correction by so-called "Change Manager", "developer" couldn't set it status "in development" -> and begin corrections in DEV system. It outputs in status bar: "NO ACTIONS IN THE WORK LIST".
  2. How should i link some urgent correction (or simply Service Message) to a specific Maintenance Cycle?
  The same problem I cannot go to the next phase, system outputs that "No Maintenance Cycle is open for the current system".
  3. And please can u explain in a simple words: Should i always make a maintenance project for using "Change Management" functions?
  4. Can we use "Change Management" for 4.0C (vers. of satellite) systems?
  Any help and tips would really appreciate.
  Best regards,
  Vladimir

  Hi,
       For configuring change management, you will have to follow the SPRO guidelines for setting up transport routes between satellite systems.
  Well i list down the activities that you need to do. Details you can find in SPRO -- > SAP Solution Manager --> Scenario Specific Settings --> Change Request Management --> Standard Configuration --> transport management System
  1) Activate Extended transport control by setting  System Parameter CTC=1 in STMS --> Systems
  2)Create Client specific transport route between satellite systems
  3) Ensure that all the systems in the domain have the same transport group.
  4)Configure or activate Single transport Strategy in STMS --> Overview --> transport routes.
  5)Activate TMS Trusted services in STMS --> Overview --> Systems --> Goto --> transport Domain --> Management Tab page --> Security option group box.
  Besides these activities, you will have to execute the SPRO IMG Activity
  SAP Solution Manager --> Basic Settings --> SAP Solution Manager System --> Activate Integration with Change Request Management
  For activity Intigration Solution Manager make the following entry
  APPL: Change Request Management
  RFC Destination : NONE
  For activity Integration Change Request Management
  make the entries in table BCOS_CUST as g
  iven in the IMG instruction.
  Now in SOLAR_PROJECT_ADMIN you can activate a maintenance project for change management by going to System Landscape --> Project Cycle
  Click the check box Activate Change request Management.
  (NOTE: The above option comes only in Solution Manager 4.0, for SOLMAN 3.2 you can directly create maintenance cycle in /n/tmwflow/cmsconf --> Distribution Routes --> Project Landscape group box .)
  Now you can create a maintenance cycle by clickin on the button Create Task List in project cycle tab page.
  Navigate to task list and activate the tasklist (Maintenance Cycle) by clicking on the status button.
  Now while creating change request ensure that you are assigning the correct ibase /component of the production system in the satellite system landscape. You have to enter the ibase component of the client of the production system to whcih the client specific transport route has been made. You can find this number in transaction IB52
  Hope now u can move on with CHARM.

• Transport classes and programs to another server

  Except for transport routing and charm copy function, do we have other ways to do so?
  for example copy or so forth.
  best regards,
  Blake Le

  Hi Blake
  SAP R/3 Correction and Transport System
  Operating system level files in the transport process:
  The SAP C program TP, requires a special file structure for the transport process. The file system is operating system dependent. TP uses a transport directory or file system, which is called /usr/sap/trans.
  The /usr/sap/trans file system is generally NFS mounted form the development system to other systems unless a system is defined as a single system in the CTS pipeline. All the sub directories should have <SID>adm as the owner and sapsys as the group; and proper read, write and execute access should be given to owner and the group. The TP imports are always performed by <SID>adm.
  The following are the subdirectories in /usr/sap/trans:
  /data
  /cofiles
  /bin
  /log
  /actlog
  /buffer
  /sapnames
  /tmp
  /usr/sap/trans/data: holds the data of transport objects after they are released . The example of a data file is R904073.DEV. The extension DEV means the data file was released from the DEV or development system.
  /usr/sap/trans/cofiles: The cofiles directory holds the command files for all change requests. These files are like a command or control files used to import the data files. The common directory for CTS system is /usr/sap/trans. After a change request is released from the source system , the data is exported immediately to the file system of the operating system. The SAP transport utility TP uses the cofile to transport a data file. The example of a file in cofiles directory is K904073.DEV.
  /usr/sap/trans/bin: holds the most important file TPPARAM in the CTS system. TPPARAM file has all the information about the CTS systems in the CTS pipeline. TPPARAM file is the parameter file for the transport program TP and it is the common file for all the systems in the CTS pipeline. As you know already that /usr/sap/trans should be NFS mounted to all the systems in a CTS pipeline, TP program has access to the TPPARAM file from all the systems. The following is an example of typical TPPARAM file for five SAP systems in the CTS pipeline:
  #@(#) TPPARAM.sap 20.6 SAP 95/03/28
  Template of TPPARAM for UNIX #
  First we specify global values for some parameters, #
  later the system specific incarnation of special parameters #
  global Parameters #
  transdir = /usr/sap/trans/
  dbname = $(system)
  alllog = ALOG$(syear)$(yweek)
  syslog = SLOG$(syear)$(yweek).$(system)
  System spezific Parameters #
  Beispiel T11 #
  DEV/dbname = DEV
  DEV/dbhost = sap9f
  DEV/r3transpath = /usr/sap/DEV/SYS/exe/run/R3trans
  QAS/dbname = QAS
  QAS/dbhost = sap8f
  QAS/r3transpath = /usr/sap/QAS/SYS/exe/run/R3trans
  TRN/dbname = TRN
  TRN/dbhost = sap17
  TRN/r3transpath = /usr/sap/TRN/SYS/exe/run/R3trans
  PRE/dbname = PRE
  PRE/dbhost = sap19f
  PRE/r3transpath = /usr/sap/PRE/SYS/exe/run/R3trans
  PRD/dbname = PRD
  PRD/dbhost = sap18f
  PRD/r3transpath = /usr/sap/PRD/SYS/exe/run/R3trans
  /usr/sap/trans/log: holds the entire log files, trace files and statistics for the CTS system. When the user goes to SE09 (workbench organizer) or SE10 (customizing organizer) transaction and opens the log for a transport, the log file for that transport will be read from /usr/sap/trans/log directory. Each change request should have a log file. Examples of log files are DEVG904073.QAS, DEVI904073.QAS and DEVV904073.QAS. The name of a log file consists of the names of the change request, the executed step, and the system in which the step was executed:
  <source system><action><6 digits>.<target system>
  Now we can analyze the above example DEVG904073. QAS. The <source system> = DEV, <action> = G or report and screen generation, <6 digits> = 904073 (these six digits numbers are exactly the same number as the six digits of the transport) and the <target system> = QAS
  Possible values for <action> are:
  A: Dictionary activation
  D: Import of application-defined objects
  E: R3trans export
  G: Report and screen generation
  H: R3trans dictionary import
  I: R3trans main import
  L: R3trans import of the command files
  M: Activation of the enqueue modules
  P: Test import
  R: Execution of reports after put (XPRA)
  T: R3trans import of table entries
  V: Set version flag
  X: Export of application-defined objects.
  /usr/sap/trans/actlog: holds action log files. The example of an action file is DEVZ902690.DEV. The following are the contents of the file:
  1 ETK220 u201C==================================================u201D u201C=================
  =============================
  1 ETK191 u201C04/30/1998u2033 Action log for request/task: u201CDEVK902690u2033
  1 ETK220 u201C==================================================u201D u201C=================
  =============================
  1 ETK185 u201C04/30/1998 18:02:32u2033 u201CMOHASX01u2033 has reincluded the request/task
  4 EPU120 Timeu2026 u201C18:02:32u2033 Run timeu2026 u201C00:00:00u2033
  1 ETK193 u201C04/30/1998 18:02:33u2033 u201CMOHASX01u2033 owner, linked by u201CMOHASX01u2033 to u201CDEVK902691u2033
  4 EPU120 Timeu2026 u201C18:02:33u2033 Run timeu2026 u201C00:00:00u2033
  1 ETK190 u201C05/04/1998 11:02:40u2033 u201CMOHASX01u2033 has locked and released the request/task
  1 ETK194 u201C05/04/1998 11:02:40u2033 **************** End of log *******************
  4 EPU120 Timeu2026 u201C11:02:40u2033 Run timeu2026 u201C00:00:09u2033
  ~
  ~u201DDEVZ902690.DEVu201D 10 lines, 783 characters
  /usr/sap/trans/buffer: transport buffer of the target systems; contains control information on which requests are to be imported into which systems and in what order the imports must occur. The /usr/sap/trans/buffer will have a directory for each system in the CTS pipeline. For example the buffer file for DEV system is /usr/sap/trans/buffer/DEV.
  /usr/sap/trans/sapnames: holds information pertaining to transport requests for each system user. There are files for each user who released change requests from the system.
  /usr/sap/trans/tmp: holds information about temporary data and log files. While the transport is occurring the Basis administrator can find a file that is related to the transport in the tmp directory; that file shows the exact status if the transport (What objects are being imported at that time).
  Important SAP delivery class and table types and tables in the CTS process:
  Delivery class
  The delivery class defines who (i.e. the SAP system itself or the customer) is responsible for maintaining the table contents. In addition the delivery class controls how the table behaves in a client copy and an upgrade. For example when you select a SAP defined profiles to perform a client copy, certain tables are selected according to their delivery class. DD02L table can show what delevery class a table belongs to.
  The following delivery classes exist:
  A: Application table.
  C: Customizing table, maintenance by customer only.
  L: Table for storing temporary data.
  G: Customizing table, entries protected against overwriting.
  E: Control table.
  S: System table, maintenance only by SAP.
  W: System table, contents can be transported via own TR objects.
  Table type
  The table type defines whether a physical table exists for the logical table description defined in the ABAP/4 Dictionary and how the table is stored on the database.
  The following are different table types in SAP:
  Transparent Tables
  There is a physical table on the database for each transparent table. The names of the physical table and the logical table definition in the ABAP/4 Dictionary are same. For every transparent table in SAP, there is a table in database. The business and application data are stored in transparent tables.
  Structure
  No data records exist on the database for a structure. Structures are used for the interface definition between programs or between screens and programs.
  Append Structure
  An Append structure defines a subset of fields which belong to another table or structure but which are treated as a separate object in the correction management. Append structures are used to support modifications.
  The following table types are used for internal purposes, for example to store control data or for continuous texts:
  Pooled table
  Pooled tables can be used to store control data (e.g. screen sequences, program parameters or temporary data). Several pooled tables can be combined to form a table pool. The table pool corresponds to a physical table on the database in which all the records of the allocated-pooled tables are stored.
  Cluster table
  Cluster tables contain continuous text, for example documentation. Several cluster tables can be combined to form a table cluster. Several logical lines of different tables are combined to form a physical record in this table type. This permits object-by-object storage or object-by-object access. In order to combine tables in clusters, at least part of the keys must agree. Several cluster tables are stored in one corresponding table on the database.
  Tables in CTS process:
  TRBAT and TRJOB:
  TRJOB and TRBAT are the major tables in the CTS process. After TP program has sent the event to the r3 system, RDDIMPDP checks table TRBAT in the target system to find out if there is an action to be performed. Mass activation, distribution, or table conversions are the examples of actions. If there is action to be performed, RDDIMPDP starts the appropriate program in the background task. RDDIMPDP then reschedules itself.
  By checking table TRJOB, RDDIMPDP automatically recognizes if a previous step was aborted, and restarts this step. For each transport request , TP program inserts an entry into table TRBAT. If the return code 9999 in this table then the step is waiting to be performed. Return code 8888 indicates that the step is active and currently being processed. A return code of 12 or less indicates that the step is finished. In addition, TP inserts a header entry to let the RDDIMPDP program know to start processing. The column return code will therefore contain a B for begin. When RDDIMPDP is started, it sets the header entry to R(un), and starts the required program. When all the necessary actions are performed for all the transport requests, the column return code contains all the return codes received, and the column TIMESTAMP contains the finishing time. The header entry is set to F(inished). TP monitors the entries in TRBAT and TRJOB tables. When the header entry in TRBAT is set to finished. The entry in TRJOB is deleted.
  Transport Tables SE06
  TDEVC - Development classes
  TASYS - Details of the delivery. Systems in the group that should automatically receive requests, have to be specified in table TASYS.
  TSYST - The transport layers will be assigned to the integration systems. ( Define all systems)
  TWSYS - Consolidation routes ( define consolidation path)
  DEVL - Transport layers are defined here
  In u201CConfiguring the CTS systemu201D section, We will learn more about the transport tables in SE06 transaction
  Programs in the CTS process:
  In the CTS table section we learned about the RDDIMPDP program. RDDIMPDP program needs to be scheduled in all the clients in an instance. It is recommended to schedule the RDDIMPDP as event driven.
  RDDPUTPP and RDDNEWPP programs can be used to schedule RDDIMPDP program in the background.
  The ABAP/4 programs that RDDIMPDP starts are determined by the transport step to be executed that is entered in the function field of table TRBAT.
  Function Job Name Description of transport Steps
  J RDDMASGL Activation of ABAP/4 dictionary objects
  M RDDMASGL Activation of match codes and lock objects
  S RDDDISOL Analysis of database objects to be converted
  N RDDGENOL Conversion of database objects
  Y RDDGENOL Conversion of matchcode tables
  X RDDDICOL Export of AD0 objects
  D RDDDIC1L Import of AD0 objects
  E RDDVERSE Version management update during export
  V RDDVERSL Version management update during import
  R RDDEXECL Execution of programs for post - import processing
  G RDDDIC3L Generation of ABAP/4 programs and screens
  Version Management:
  One of the important features of Workbench Organizer is Version Management. This feature works for all the development objects. Using the version management feature the users can compare and retrieve previous versions of objects.
  Version management provides for comparisons, restore of previous versions, documentation of changes and assistance in the adjustment of data after upgrading to a new release. With the release of a change request, version maintenance is automatically recorded for each object. If an object in the system has been changed N times, it will have N delta versions and one active version. To display version management, for ABAPs use transaction SE38 and for tables, domains and data elements use SE11. The path to follow is Utilities -> Display version. Using version management the users can view existing version for previously created ABAP code, make changes to the code, compare code versions and restore original version of the code. Now the users will be restore previous versions without cut and paste steps of the past.
  TP and R3trans program:
  The basis administrator uses TP program to transport SAP objects from one system to another. TP is a C program delivered by SAP that runs independently of the R/3 system. TP program uses the appropriate files located in a common transport directory /usr/sap/trans. TP starts C programs, ABAP/4 programs and special operating system commands to its job. R3trans is one of the most important utility program called by TP. Before using the TP program, the basis administrator needs to make sure that the CTS system is setup properly and the right version of TP is running in the system. The TP program is located in the run time directory /usr/sap/<SID>/SYS/exe/run directory. It is automatically copied in the install process. A global parameter file TPPARAM that contains the databases of the different target systems and other information for the transport process controls TP. The global parameter file determines which R3trans is used for each system. If the parameter r3transpath is not defined properly then no export and import can be done. The basis administrator should make sure that the default value u201Cr3transpathu201D is properly defined. Later in this chapter we will learn more about TP and R3trans; also we are going to see how they are used.
  Configuring the TPPARAM file:
  Each time TP is started, it must know the location of the global parameter file. As we have seen before TPPARAM file should be in directory /usr/sap/trans/bin. The parameters in TPPARAM can either global (valid for each and every system in the cts pipeline) or local to one system. Th parameters are either operating system dependant (these parameters preceded by a keyword corresponding to the specific operating system) or database dependant (contain a keyword corresponding to a specific database system).
  The global parameter file provides variables that can be used for defining parameters. The variables can be defined in format: $(xyz). The brackets can be substituted with the u201C\u201D-character if required.
  The following pre-defined variables are available for the global parameter file:
  $(cpu1): The CPU name can be sun or as4 for example. In heterogeneous networks this variable is very important.
  $(cpu2): Acronym for the name of the operating system. The example for this variable can be
  hp-ux, or sunos . This is an operating system specific variable.
  $(dname): Used for the day of the week (SUN,MON,u2026.).
  $(mday): Used for the day of the current month (01-31).
  $(mname): Used for the name of the month (JANu2026DEC).
  $(mon): Used for the Month (01-12).
  $(system): R/3 System name.
  $(wday): Day of the week (00-06, Sunday=00, Monday=01, Tuesday=02 and so on).
  $(yday): Day of the current year (001-366). Using the number any day of the year can be chosen.
  $(year): Year (Example:1998 or 1999).
  $(syear): Short form of the year (two positions).
  $(yweek): Calendar week (00-53). The first week begins with the first Sunday of the year.
  For the database connection:
  The transport environment also needs parameters to connect to the R/3 System database. As we know already the every instance in the R/3 CTS pipeline has its own database, therefore specific parameters should be defined for each database system. From dbtype parameter of RSPARAM file, TP program identifies the database system.
  The two parameters u201Cdbnameu201D and u201Cdbhostu201D are required for ORACLE databases.
  DBHOST: is the name of the computer on which the database processes execute. TCP/IP name of the host if NT is being used.
  DBNAME: is the name of the database instance.
  As of Release 3.0E, two new parameters have been introduced.
  DBLOGICALNAME: The default value is $(system). The logical name that was used to install the database.
  DBCONFPATH: The default value is $(transdir).
  The parameters u201Cdbnameu201D and u201Cdbhostu201D are also used for INFORMIX databases in an installation:
  DBHOST: Same as Oracle.
  DBNAME: Name of the database instance, uppercase and lowercase are distinguished here.
  INFORMIXDIR : u201C/informix/<SAPSID>u201D is the default value. Defines the directory namewhere the database software can be found.
  INFORMIXSQLHOSTS: u201C$(informixdir)/etc/sqlhosts[.tli|.soc]u201Cis default value under Unix. The name of the SQLhosts file with its complete path is defined with this parameter.
  INFORMIX_SERVER: u201C$(dbhost)$(dbname)shmu201D is the default value. The name of the database server may be specified for a local connect.
  INFORMIX_SERVERALIAS: u201C$(dbhost)$(dbname)tcpu201Dis the default vlue. The name of the database server can be specified for a remote connect.
  For Microsoft SQL Server database the two parameters u201Cdbnameu201D and u201Cdbhostu201D are also required. DBHOST: The TCP/IP name of the host on which the database is running.
  DBNAME: The database instance name.
  For DB2 in AS/400 only u201Cdbhostu201D is required.
  DBHOST: System name of the host on which the database is running.
  If theu201DOptiConnectu201D is used, the following line should be specified:
  OPTICONNECT 1
  For DB2/ AIX
  The two parameters u201Cdbnameu201D and u201Cdbhostu201D are required
  DBHOST: The host on which the database processes are running. It is the TCP/IP name of the host for Windows NT (As we have seen in the earlier examples).
  DBNAME: Database instance name.
  The DB2 for AIX Client Application Enabler Software must also be installed on the host on which tp is running.
  ALLLOG: u201CALOGu201D $(syear) $(yweek)u201Dis the default value. This variable can be used in TPPARAM file to specify the name of a file in which tp stores information about every transport step carried out for a change request anywhere in the transport process. The file always resides in the log directory.
  SYSLOG: u201CSLOG $(syear) $(yweek).$(system)u201D is the default value. This variable can be used to name a file in which tp stores information about the progress of import actions in a certain R/3 System. The file does not store information for any particular change request. The file always resides in the log directory.
  tp_VERSION: Zero is the default value. If this parameter is set to not equal to zero, a lower version of tp may not work with this TPPARAM file. If the default value (zero) is set, the parameter has no affect.
  STOPONERROR: (Numeric value) The default value is 9. When STOPONERROR is set to zero, tp is never stopped in the middle of an u201Cimportu201D or u201Cputu201D call. When STOPONERROR is set to a value greater than zero, tp stops as soon as a change request generates a return code that is equal to or greater than this value (The numeric value of the STOPONERROR parameter is stored in the variable BADRC). Change requests, which still have to be processed for the current step, are first completed. A u201CSYNCMARKu201D in the buffer of the R/3 System involved, sets a limit here. tp divides the value of this parameter between two internal variables. STOPONERROR itself is treated as a boolean variable that determines whether tp should be stopped, if the return code is too high.
  REPEATONERROR (Numeric value too): The default value is 9. The REPEATONERROR parameter is similar to STOPONERROR. The difference is, REPEATONERROR specifies the return code up to which a change request is considered to be successfully processed. Return codes less than REPEATONERROR are accepted as u201Cin Orderu201D. Change requests that were not processed successfully stay in the buffer.
  NEW_SAPNAMES: Default value is u201CFALSEu201D. A file is created for each user of the R/3 System group in the u201Csapnamesu201D subdirectory of the transport directory. Except some of the operating system,the name of the user is the name of the file. It is very important to remember hat the special characters or length of the file name could cause problems. If all the R/3 Systems in the transport group have at least Release level 3.0.; TP program is efficient to handle this problem. The user names are modified to create file names that are valid in all operating systems and the real user names are stored in a corresponding file.
  Though we have seen so many parameters, for the minimum configuration the following two parameters are very important.
  TRANSDIR: specifies the name of the common transport directory. The following is a typical example from TPPARAM of Unix as we have seen before.
  transdir = /usr/sap/trans/
  DBHOST: contains the name of the database host. In Windows NT environment, this is the TCP/IP host name. The following is an example in Unix:
  DEV/dbname = DEV
  DEV/dbhost = sap9f
  DEV/r3transpath = /usr/sap/DEV/SYS/exe/run/R3trans
  For TP, to control u2018Start and Stopu2019 command files and database in R/3 the following important parameters are specified in TPPARAM:
  Parameters for the tp Function u201CPUTu201D: LOCK_EU (boolean) default value is u201CTRUEu201D. Though from version 3.1 onward the tp put command is used seldom in cts process still it is important to know how this parameter works. When u201Ctp putu201D is used, it changes the system change option . If the parameter is set to u201CFALSEu201D nothing gets changed. If the parameter is set to u201CTRUEu201D, the system change option is set to u201CObjects cannot be changedu201D at the beginning of the call, and gets changed back to its previous value at the end of the call. The u201Ctp putu201D command will give the exact status of the locking mechanism.
  LOCKUSER (used as boolean value): Default value is u201CTRUEu201D. This parameter is about the user login while tp put call is executed. If this parameter is set to u201CFALSEu201D, no locking mechanism for the users takes affect. If this parameter is defined as u201CTRUEu201D then a character is set in the database level; so only DDIC and SAP* can log on to the system. Users that have already logged on are not affected (this is a reason for activating the parameters STARTSAP and STOPSAP). The charactertor is removed at the end of the call, and all the users can log on to the SAP R/3 System again.
  STARTSAP: Default value is u201D u201C.or u201CPROMPTu201D for Windows NT . This parameter is used by TP to start an R/3 System. It is not necessary for the clients to make tp start and stop R/3 system..
  STOPSAP: Default value is u201D u201Cor u201CPROMPTu201D for Windows NT. TP uses this parameter to stop an R/3 System.
  STARTDB: Default value is u201D u201C. TP uses the value of this parameter to start the database of an R/3 System.
  The parameter is not active under Windows NT.
  STOPDB: Default value is u201D u201C. TP uses the value of this parameter to stop the database of an R/3 System.
  This parameter is not active under Windows NT.
  The above parameters in UNIX can be used as following:
  STARTSAP = startsap R3
  STOPSAP = stopsap R3
  STARTDB = startsap db
  STOPDB = stopsap db
  In Windows NT:
  STARTSAP =
  $(SAPGLOBALHOST)\sapmnt\$(system)\sys\exe\run\startsap.exe
  R3 <SID> <HOST NAME> <START PROFILE>
  STOPSAP =
  $(SAPGLOBALHOST)\sapmnt\$(system)\sys\exe\run\stopsap.exe
  R3 <SID> <HOST NAME> <INSTANCE> <PROFILE PATH + Instance profile>
  The parameters STARTDB and STOPDB are not active under Windows NT.
  Parameters for the tp function u201CCLEAROLDu201D
  DATALIFETIME (Numeric): Default value is u201C200u2033. When the data file has reached a minimum age, it is moved to the subdirectory old data with tp check. tp clearold all. The life span of the data files in the data sub directory can be set in days with this all, parameter.
  OLDDATALIFETIME (Numeric): Default value is u201C365u2033. When a file located in the olddata subdirectory is no longer needed for further actions of the transport system and has reached a minimum age, it is removed with tp check.all, tp clearold all. The minimum age in days can be set with this parameter.
  COFILELIFETIME (Numeric): Default value is u201C365u2033. This parameter is used just like DATALIFETIME parameter.
  LOGLIFETIME (Numeric): Default value is u201C200u2033. This parameter applies to the life span of the log files. When the log files in log subdirectory is no longer needed for the transport system and has reached a minimum age, it is deleted with the calls tp check.all, tp clearold all. The minimum age in days can be defined with this parameter.
  The Three Key Utilities of the CTS system (TP, R3trans and R3chop):
  TP: Earlier in this chapter we have seen the objectives of TP. The TP transport control program is a utility program that helps the user to transport objects from one system to another. TP program is the front-end for the utility R3trans. TP stands for u201CTransports and Putsu201D. To make the TP work successfully the CTS system needs to be correctly configured. The following steps are very important for TP to run properly.
  The transport directory /usr/sap/trans must be installed and NFS mounted to all the systems in the CTS pipe line.
  RDDIMPDP program must be running (event driven is recommended) in each client. RDDIMPDP can be scheduled in the background by executing RDDNEWPP or RDDPUTPP. Use the tp checkimpdp <sap sid> command in /usr/sap/trans/bin directory as <sid>adm user to check RDDIMPDP program.
  Use the tp connect <sap sid> command in /usr/sap/trans/bin directory to see whether the tp program is connecting to the database successfully or not. To run TP command the user has to logon as <sid>adm in source or target system.
  The R/3 Systems in the CTS pipeline must have different names.
  The Global CTS Parameter File TPPARAM must be correctly configured.
  The source system (for the export) and target system ( for the import) must have at least two background work processes. TP always schedules the C class job, so if all the background jobs are defined as A class job then there will be problems in transport steps.
  Important Tips :.It is always better to have the up to date TP version installed in your system. A user can ftp a current version of TP from SAPSERV4 of SAP. Though R3trans and other utility programs can be used to do the transport, it is recommended to use TP whenever possible for the following reasons..
  The exports and imports are done separately using TP program. For example: when a transport is released from the system, the objects are exported from the source database to the operating system and then the import phase starts to transport those objects to the target system.
  TP takes care of the order of the objects. The order, that was followed to export the objects; the same order will be followed to import them to the target database.
  The TP command processes all change requests or transports in the SAP system buffer that have not yet been imported successfully. All the import steps are executed automatically after TP calls R3trans program to execute the following necessary steps:
  Dictionary Import: ABAP/4 dictionary objects will be imported in this step.
  Dictionary Activation: Name tabs or runtime descriptions will be written inactively. The R/3 system keeps running until the activation phase is complete. The enqueue modules are the exceptions in the running phase. After the activation of new dictionary structure the new actions are decided to get the runtime objects to the target system.
  Structure conversion: If necessary the table structure is changed in this phase.
  Move Nametabs: The new ABAP/4 Dictionary runtime objects which were inactive up to now are moved into the active runtime environment in this process. The database structures are adjusted accordingly. From the first step to the Main import step inconsistencies can occur to the R/3 system. After the main import phase all the inconsistency ca be solved.
  Main import with R3trans: All the data are imported completely and the system comes to a consistent state.
  Activation of enqueue-objects: The enqueue-objects cannot be activated in the same way as the objects of the ABAP/4 Dictionary, so they have to be activated after the main import in this step. They are then used directly in the running system.
  Structure Conversion of match codes, Import application defined objects, versioning and execution of user defined activities are some of the steps after activation of enqueue-objects. The next step is generation of ABAP/4 programs and screens, where all the programs and screens associated with the change request are generated. When all the import steps are completed successfully, the transport request is removed from the import buffer.
  It is recommended by SAP to schedule regular periods for imports into the target system (e.g. daily, weekly or monthly). Shorter periods between imports are not advisable. The transport to production should not be done in the off hours when the users are not working
  TP can be started with different parameters. The u201Ctp helpu201D command can help user to generate a short description about the use of the command.
  The following are the some important commands of TP:
  For export:
  tp export <change request>: The complete objects in the request from the source system will be transported. This command also used by SAP System when it releases a request.
  tp r3e <change request>: R3trans export of one transport request.
  tp sde <change request>: Application defined objects in one transport request can be exported.
  tp tst <change request> <SAP system >: The test import for transport request can be done using this command.
  tp createinfo <change request>: This command creates a information file that is automatically done during the export.
  tp verse <request>: This command creates version creates versions of the objects in the specified request.
  To Check the transport buffer, global parameter file and change requests:
  tp showbuffer <sid>: Shows all the change requests ready to be imported to the target system.
  tp count <sid>: Using this command users can find out the number of requests in the buffer waiting for import.
  tp go <sid>: This command shows the environment variables needed for the connection to the database of the <sid> or target system.
  tp showparams <sid>: All the values of modifiable tp parameters in the global parameter file. The default value is shown for parameters that have not been set explicitly.
  To import the change requests or transports:
  tp addtobuffer <request>.<sid>: If a change request is not in the buffer then this command is used to add it to the buffer, before the import step starts.
  tp import all <sid>: This command imports all the change requests from the buffer to the target system.
  tp put <sid>: The objective of this command is same as u201Ctp import all <sid>u201D, but this command locks the system. This command also starts and stops the SAP system, if the parameters startsap and stopsap parameters are not set to u201D u201C.
  tp import <change request> <sid>: To import a single request from the source system to target system.
  tp r3h <change request>| all <sid>: Using this command user can import the dictionary structures of one transport or all the transport from the buffer.
  tp act <change request>|all <sid>: This command activates all the dictionary objects in the change request.
  tp r3i <change request> | all <sid>: This command imports everything but dictionary structures of one.
  tp sdi <change request>|all <sid>: Import application-defined objects.
  tp gen <change request>|all <sid>: Screen and reports are generated using this command.
  tp mvntabs <sid>: All inactive nametabs will be activated with this command.
  tp mea <change request>|all <sid>: This command will activate the enqueue modules in the change request.
  When you call this command, note the resulting changes to the import sequence.
  Additional tp utility options:
  tp check <sid>|all (data|cofiles|log|sapnames|verbose): User uses this command to find all the files in the transport directory that are not waiting for imports and they have exceeded the minimum time specified using the COFILELIFETIME, LOGFILELIFETIME, OLDDATALIFETIME and DATALIFETIME parameters of TPPARAM file.
  tp delfrombuffer <request>.<sid>: This command removes a single change request from the buffer. In case of TMS, the request will be deleted from the import queue.
  tp setstopmark <sid>: A flag is set to the list of requests ready for import into the target system. When the user uses the command tp import all <sapsid> and tp put <sapsid>, the requests in front of this mark are only processed. After all the requests in front of the mark have been imported successfully, the mark is deleted.
  tp delstopmark <sid>: This command deletes the stop mark from the buffer if it exists.
  tp cleanbuffer <sapsid>: Removes all the change requests from the buffer that are ready for the import into the target system.
  tp locksys <sid>: This command locks the system for all the users except SAP* and DDIC. The users that have already logged on are not affected by the call.
  tp unlocksys <sid>: This command unlocks the system for all the users.
  tp lock_eu <sid>: This command sets the system change option to u201Csystem can not be changedu201D tmporarily.
  tp unlock_eu <sid>: This command unlocks the system for all the changes.
  tp backupall <sid>: This command starts a complete backup using R3trans command. It uses /usr/sap/trans/backup directory for the backup.
  tp backup delta <sid>: Uses R3trans for a delta backup into /usr/sap/trans/backup directory.
  tp sapstart <sid>: To start the R/3 system.
  tp stopsap <sid>: To stop the R/3 system.
  tp dbstart <sid>: To start the database.
  tp dbstop <sid>: To stop the database.
  Unconditional modes for TP: Unconditional modes are used with the TP program and these modes are intended for the special actions needed in the transport steps. Using unconditional mode user can manipulate the rules defined by the workbench organizer. The unconditional mode should be used when needed, otherwise it might create problems for the R/3 system database. Unconditional mode is used after the letter u201CUu201D in the TP command. Unconditional mode can be a digit between 0 to 9 and each has a meaning to it. The following is a example of a import having unconditional mode.
  tp import devk903456 qas client100 U12468
  0: Called a overtaker; change request can be imported from buffer without deleting it and then uncoditional mode 1 is used to allow another import in the correct location.
  1: If U1 is used with the export then it ignores the correct status of the command file; and if it is used with import then it lets the user import the same change request again.
  2: When used with tp export, it dictates the program to not to expand the selection with TRDIR brackets. If used in tp import phase, it overwrites the originals.
  3: When used with tp import, it overwrites the system-dependant objects.
  5: During the import to the consolidation system it permits the source systems other than the integration system.
  6: When used in import phase, it helps to overwrite objects in unconfirmed repairs.
  8: During import phase it ignores the limitations caused by the table classification.
  9: During import it ignores that the system is locked for this kind of transport.
  R3trans: TP uses R3trans program to transport data from one system to another in the CTS pipeline. efficient basis administrator can use R3trans directly to export and import data from and into any SAP systems. Using this utility transport between different database and operating system can e done without any problems. Different versions of R3trans are fully compatible with each other and can be used for export and import. The basis administrator has to be careful using R3trans for different release levels of R/3 software; logical inconsistency might occur if the up to date R3trans is not used for the current version of R/3 system.
  The syntax for using the control file is following:
  R3trans [<options>] <control file> (several options used at the same time; at least one option must be there)
  For example: R3trans u2013u 1 u2013w test.log test
  In the above example a unconditional mode is used, a log file u201Ctest.logu201D file is used to get the log result and a control file u201Ctestu201D, where the instructions are given for the R3trans to follow. The user needs to logon as <sid>adm to execute R3trans.
  The following options are available for the R3trans program:
  R3trans -d : This command is used to check the database connection .
  R3trans -u <int>: Unconditional mode can be used as we have seen in the above example.
  R3trans -v : This is used for verbose mode. It writes additional details to the log file
  R3trans -i <file>: This command directly imports data from data file without a control file.
  R3trans -l <file>: This provides output of a table of contents to the log file.
  R3trans -n : This option provides a brief information about new features of R3trans.
  R3trans u2013t: This option is used for the test mode. All modifications in the database are rolled back.
  R3trans -c <f1> [<f2>]: This command is used for conversion. The <f1> file will be copied to <f2> file after executing a character set conversion to the local character set.
  Important tips: Do not confuse the backup taken using R3trans with database backup. The backups taken using R3trans are logical backups of objects. In case something happens to the SAP system these backups can not be used for recovery. R3trans backups can be only used to restore a copy of a particular object that has been damaged or lost by the user.
  R3trans -w <file>: As we have seen in the above example this option can be used to write to a log file. If no file is mentioned then trans.log is default directory for the log.
  R3trans also can be used for the database backup.
  R3trans u2013ba: This command is used for a complete backup. we will see in the next paragraph how to use
  the control file for the backup.
  R3trans u2013bd: This command is used for a delta backup if the user does not want a complete backup.
  R3trans u2013bi: This option will display backup information.
  The following are some of the examples of control files:
  We have already learned how to use a command for the logical backup of the objects in the database. To get a complete backup the following example control file can be used.
  backup all
  file = /usr/sap/trans/backall
  The option u201Cfile = u2026u201D is the name of the directory into which the data files are to be written. If you are taking a complete backup of DEV system then the backup file is going to look like u201CDEV.A000.bcku201D the next complete
  Reward if useful
  Regards
  divya

• Tab missing in Transaction /n/TMWFLOW/CMSCONF

  We have upgraded our SMR 3.2 to SMR 4.0, in SMR 3.2 i can able to see the tab named "Distribution Routes" using /TMWFLOW/CMSCONF transaction.when i used the same t-code SMR 4.0 , i can only able to see System Change Options and Critical objects,Other tabs are not in visible mode ??? how can we retrive the same tab . or else is there any other t-code for Distribution routes ???? guide me ..
  im struck up while following the SPRO settings in ChaRM.Send me is there any step by step weblogs are available ???

  Hi Prakash,
  If you are trying to create project cycles with /TMWFLOW/CMSCONF-> Distribution Routes-> Project environment, go to SOLAR_PROJECT_ADMIN -> System landscape-> Project cycles. With Release 4.0, some functions that existed in 3.20 outside of the original tools of the Solution Manager have been reintroduced.
  If you need to go to Transport Domains and to navigate to TMS system configuration, go to Transaction SMSY-> Environment -> Domain Controller Overview.
  If you need this tab for other function, let us know.
  Regards,
  Raquel Cunha.

• Re: /n/tmwflow/cmsconf - how to find tcode central configuration

  Hi gurus,
  Iam configuring the ChaRM for this i have done the IMG,TMS all the activities but i can t find the systems in the /tmwflow/cmsconf transaction. The distribution button and the sceduling button are hided ,how to enable it !
  solutions awarded for sure!
  regards,
  esr kumar

  Hey Thom,
  Issue 1).
  In SOLAR_PROJ_ADMIN, the reason you get those red icons because settings which are maintained are not as recemmended by SAP,
  For e.g
  if you define a Production sytem in your project landscape, then Cross-client changes are NOT permitted, however its permitted if it were a Development system.
  Just click on the red icon and then on your right, you will see the tab where you get know what went wrong and correct it if neccssary.
  Issue 2)
  With Solman 4.0 distribution routes tabs are not present.
  There are *.sim files and configuration available for Change request management in sap marketplace, but they are valid only for SOLMAN 3.2.
  This is where you get them.
  <a href="https://websmp207.sap-ag.de/form/sapnet?_SHORTKEY=01100035870000633637&">https://websmp207.sap-ag.de/form/sapnet?_SHORTKEY=01100035870000633637&</a>
  Just click on Techincal or functional roles on your right and there you get everthing.
  For SOLMAN 4.0, there are no config guide or SIM files available yet.
  Please Reward for usefull post and close this thread if your problem is solved
  Regards,
  Anand.