Computer Drive User Manual
Table Of Contents
- Front cover
- Contents
- Notices
- Preface
- Summary of changes
- Part 1 Overview
- Chapter 1. Introduction
- Chapter 2. Copy Services architecture
- Part 2 Interfaces
- Chapter 3. DS Storage Manager
- Chapter 4. DS Command-Line Interface
- Chapter 5. System z interfaces
- Part 3 FlashCopy
- Chapter 6. FlashCopy overview
- Chapter 7. FlashCopy options
- 7.1 Multiple relationship FlashCopy
- 7.2 Consistency Group FlashCopy
- 7.3 FlashCopy target as a Metro Mirror or Global Copy primary
- 7.4 Incremental FlashCopy - refresh target volume
- 7.5 Remote FlashCopy
- 7.6 Persistent FlashCopy
- 7.7 Data set FlashCopy
- 7.8 Reverse restore
- 7.9 Fast reverse restore
- 7.10 Options and interfaces
- Chapter 8. FlashCopy ordering and activation
- Chapter 9. FlashCopy interfaces
- Chapter 10. FlashCopy performance
- Chapter 11. FlashCopy examples
- Part 4 Metro Mirror
- Chapter 12. Metro Mirror overview
- Chapter 13. Metro Mirror options and configuration
- Chapter 14. Metro Mirror interfaces
- 14.1 Metro Mirror interfaces - overview
- 14.2 TSO commands for Metro Mirror management
- 14.3 ICKDSF
- 14.3.1 Metro Mirror management with ICKDSF
- 14.3.2 Display the Fibre Channel Connection Information Table
- 14.3.3 PPRCOPY DELPAIR
- 14.3.4 PPRCOPY DELPATH
- 14.3.5 PPRCOPY ESTPATH
- 14.3.6 PPRCOPY ESTPAIR
- 14.3.7 PPRCOPY FREEZE
- 14.3.8 PPRCOPY QUERY
- 14.3.9 PPRCOPY RECOVER
- 14.3.10 PPRCOPY SUSPEND
- 14.3.11 PPRCOPY RUN
- 14.3.12 Refreshing the VTOC
- 14.4 DS Command-Line Interface
- 14.5 DS CLI command- examples
- 14.6 DS Storage Manager GUI
- 14.7 ANTRQST API
- Chapter 15. Metro Mirror performance and scalability
- Chapter 16. Metro Mirror examples
- Part 5 Global Copy
- Chapter 17. Global Copy overview
- Chapter 18. Global Copy options and configuration
- Chapter 19. Global Copy performance and scalability
- Chapter 20. Global Copy interfaces
- Chapter 21. Global Copy examples
- Chapter 22. Global Mirror overview
- Part 6 Global Mirror
- Chapter 23. Global Mirror options and configuration
- 23.1 Terminology used in Global Mirror environments
- 23.2 Create a Global Mirror environment
- 23.3 Modify a Global Mirror session
- 23.4 Remove a Global Mirror environment
- 23.5 Global Mirror with multiple storage disk subsystems
- 23.6 Connectivity between local and remote site
- 23.7 Recovery scenario after primary site failure
- 23.7.1 Normal Global Mirror operation
- 23.7.2 Primary site failure
- 23.7.3 Failover B volumes
- 23.7.4 Check for valid Consistency Group state
- 23.7.5 Set consistent data on B volumes
- 23.7.6 Reestablish the FlashCopy relationship between B and C volumes
- 23.7.7 Restart the application at the remote site
- 23.7.8 Prepare to switch back to the local site
- 23.7.9 Return to local site
- 23.7.10 Conclusions
- Chapter 24. Global Mirror interfaces
- 24.1 Global Mirror interfaces - overview
- 24.2 Different interfaces for the same function
- 24.3 Global Mirror management using TSO commands
- 24.3.1 Establish a Global Mirror environment
- 24.3.2 Define paths
- 24.3.3 Establish Global Copy volume pairs
- 24.3.4 Establish FlashCopy relationships for Global Mirror
- 24.3.5 Define a Global Mirror session
- 24.3.6 Populate a Global Mirror session with volumes
- 24.3.7 Start a Global Mirror session
- 24.3.8 Query a Global Mirror session
- 24.4 DS CLI to manage Global Mirror volumes in z/OS
- 24.5 Global Mirror management using ICKDSF
- 24.5.1 Establish a Global Mirror environment
- 24.5.2 Define paths
- 24.5.3 Establish Global Copy pairs
- 24.5.4 Establish FlashCopy relationships
- 24.5.5 Define a Global Mirror session
- 24.5.6 Add volumes to a session
- 24.5.7 Start Global Mirror
- 24.5.8 Query an active Global Mirror session
- 24.5.9 Remove a Global Mirror environment
- 24.5.10 Stop the Global Mirror session
- 24.5.11 Remove volumes from Global Mirror
- 24.5.12 Un-define the Global Mirror session
- 24.5.13 Withdraw FlashCopy relationships
- 24.5.14 Delete Global Copy pairs
- 24.5.15 Remove all paths
- 24.6 ANTRQST macro
- 24.7 DS Storage Manager GUI
- Chapter 25. Global Mirror performance and scalability
- Chapter 26. Global Mirror examples
- 26.1 Global Mirror examples - configuration
- 26.2 Global Mirror query examples with TSO
- 26.3 Set up the Global Mirror environment using TSO
- 26.4 Primary site failure and recovery management with TSO
- 26.4.1 Primary site failure
- 26.4.2 Stop a Global Mirror session
- 26.4.3 Failover from B to A volumes
- 26.4.4 Check Global Mirror FlashCopy status between B and C volumes
- 26.4.5 Create a data consistent set of B volumes
- 26.4.6 Optionally create a data consistent set of D volumes
- 26.4.7 Create a data consistent set of C volumes
- 26.4.8 Prepare to return to the local site
- 26.4.9 Replicate the changes from B to A
- 26.4.10 Return to the local site and resume Global Mirror
- 26.5 Remove Global Mirror environment using TSO
- 26.6 Planned outage management using ICKDSF
- 26.7 Remove a Global Mirror environment using ICKDSF
- 26.8 Query device information with ICKDSF
- 26.9 Set up a Global Mirror environment using DS SM
- 26.10 Set up a Global Mirror environment using the DS CLI
- 26.11 Control and Query Global Mirror with the DS CLI
- 26.12 Site switch basic operations using the DS CLI
- 26.13 Remove the Global Mirror environment with the DS CLI
- Part 7 Interoperability
- Chapter 27. Combining Copy Service functions
- Chapter 28. Interoperability between DS6000 and DS8000
- 28.1 DS6000 and DS8000 Copy Services interoperability
- 28.2 Preparing the environment
- 28.2.1 Minimum microcode levels
- 28.2.2 Hardware and licensing requirements
- 28.2.3 Network connectivity
- 28.2.4 Creating matching user IDs and passwords
- 28.2.5 Updating the DS CLI profile
- 28.2.6 Adding the Storage Complex
- 28.2.7 Volume size considerations for Remote Mirror Copy
- 28.2.8 Determining DS6000 and DS8000 CKD volume size
- 28.3 RMC: Establishing paths between DS6000 and DS8000
- 28.4 Managing Metro Mirror or Global Copy pairs
- 28.5 Managing DS6000 to DS8000 Global Mirror
- 28.6 Managing DS6000 and DS8000 FlashCopy
- 28.7 z/OS Global Mirror
- Part 8 Solutions
- Chapter 29. Interoperability between DS6000 and ESS 800
- 29.1 DS6000 and ESS 800 Copy Services interoperability
- 29.2 Preparing the environment
- 29.2.1 Minimum microcode levels
- 29.2.2 Hardware and licensing requirements
- 29.2.3 Network connectivity
- 29.2.4 Creating matching user IDs and passwords
- 29.2.5 Updating the DS CLI profile
- 29.2.6 Adding the Copy Services domain
- 29.2.7 Volume size considerations for RMC (PPRC)
- 29.2.8 Volume address considerations on the ESS 800
- 29.3 RMC: Establishing paths between DS6000 and ESS 800
- 29.4 Managing Metro Mirror or Global Copy pairs
- 29.5 Managing ESS 800 Global Mirror
- 29.6 Managing ESS 800 FlashCopy
- Chapter 30. IIBM TotalStorage Rapid Data Recovery
- Chapter 31. IBM TotalStorage Productivity Center for Replication
- 31.1 IBM TotalStorage Productivity Center
- 31.2 Where we are coming from
- 31.3 What TPC for Replication provides
- 31.4 Copy Services terminology
- 31.5 TPC for Replication terminology
- 31.6 TPC for Replication session types
- 31.7 TPC for Replication session states
- 31.8 Volumes in a copy set
- 31.9 TPC for Replication and scalability
- 31.10 TPC for Replication system and connectivity overview
- 31.11 TPC for Replication monitoring and freeze capability
- 31.12 TPC for Replication heartbeat
- 31.13 Supported platforms
- 31.14 Hardware requirements for TPC for Replication servers
- 31.15 TPC for Replication GUI
- 31.16 Command Line Interface to TPC for Replication
- Chapter 32. GDPS overview
- Appendix A. Concurrent Copy
- Appendix B. SNMP notifications
- Appendix C. Licensing
- Appendix D. CLI migration
- Related publications
- Index
- Back cover
504 IBM System Storage DS6000 Series: Copy Services with IBM System z
Near transparent D/R solution
Recovery Time Objective (RTO) less than an hour
Recovery Point Objective (RPO) of zero (optional)
Protects against localized area disasters with a typical distance between sites limited to up
to 100 km fiber distance
The GDPS/PPRC solution offering combines System z Parallel Sysplex capability and ESS,
DS6000, and/or DS8000 Metro Mirror disk mirroring technology to provide a Business
Continuity solution for IT infrastructures that have System z at the core. GDPS/PPRC offers
efficient workload management, system resource management, Business Continuity or
Disaster Recovery for z/OS servers and open system data, and provides data consistency
across all platforms using the Metro Mirror Consistency Group function.
The GDPS solution uses automation technology to provide end-to-end management of
z/Servers, disk mirroring, tape mirroring, and workload shutdown and startup. GDPS will
manage the infrastructure to minimize or eliminate the outage during a planned or unplanned
site failure. Critical data is disk mirrored, and processing is automatically restarted at an
alternate site in the event of a primary planned site shutdown or site failure.
GDPS/PPRC automation provides scalability to insure data integrity at a very large number of
volumes, across hundreds or thousands of Metro Mirror pairs.
32.1.2 PPRC and HyperSwap
Exclusive to GDPS in the PPRC environment is HyperSwap. This function is designed to
broaden the near continuous availability attributes of GDPS/PPRC by extending the Parallel
Sysplex redundancy to disk subsystems. The HyperSwap function can help significantly
reduce the time needed to switch to the secondary set of disks while keeping the z/OS
systems active together with their applications.
GDPS/PPRC V3.2, the HyperSwap function, exploits the Metro Mirror Failover/Failback
(FO/FB) function.
For planned reconfigurations, FO/FB may reduce the overall elapsed time to switch the disk
subsystems, thereby reducing the time that applications may be unavailable to users.
For unplanned reconfigurations, FO/FB allows the secondary disks to be configured in the
suspended state after the switch and record any updates made to the data. When the failure
condition has been repaired, resynchronizing back to the original primary disks requires only
the changed data to be copied, thus eliminating the need to perform a full copy of the data.
The window during which critical data is left without Metro Mirror protection following an
unplanned reconfiguration is thereby minimized.
32.1.3 RCMF/PPRC overview
Remote Copy Management Facility/PPRC (RCMF/PPRC) is the name given to a subset of
the GDPS/PPRC offerings. RCMF/PPRC includes the storage interface management
functions only.
RCMF/PPRC provides panels and code that execute under NetView®, and an operator
interface for easier management of a remote copy configuration in setup, initialization, and
any planned outage operational mode. This provides benefits for businesses looking to
improve their management of PPRC for normal running circumstances.
Note that RCMF/PPRC does not provide any monitoring capability and is not designed to
notify the operator of an error in the remote copy configuration. Thus RCMF does not support