IBM
RAMAC Virtual Array,
Peer-to-Peer Remote Copy,
and IXFP/SnapShot for VSE/ESA
Alison Pate Dionisio Dychioco Guenter Rebmann Bill Worthington
International Technical Support Organization
This book was printed at 240 dpi (dots per inch). The final production redbook with the RED cover will
be printed at 1200 dpi and will provide superior graphics resolution. Please see “How to Get ITSO
Redbooks” at the back of this book for ordering instructions.
SG24-5360-00
Download from Www.Somanuals.com. All Manuals Search And Download.
SG24-5360-00
International Technical Support Organization
IBM
RAMAC Virtual Array,
Peer-to-Peer Remote Copy,
and IXFP/SnapShot for VSE/ESA
January 1999
Download from Www.Somanuals.com. All Manuals Search And Download.
Take Note!
Before using this information and the product it supports, be sure to read the general information in
Appendix E, “Special Notices” on page 65.
First Edition (January 1999)
This edition applies to Version 6 of VSE Central functions, Program Number 5686-066, Version 2, Release 3.1 of
VSE/ESA, Program Number 5590-VSE, and Version 1, Release 16 of Initialize Disk (ICKDSF), Program Number
5747-DS2 for use with the VSE/ESA operating system.
Comments may be addressed to:
IBM Corporation, International Technical Support Organization
Dept. QXXE Building 80-E2
650 Harry Road
San Jose, California 95120-6099
When you send information to IBM, you grant IBM a non-exclusive right to use or distribute the information in any
way it believes appropriate without incurring any obligation to you.
Copyright International Business Machines Corporation 1999. All rights reserved.
Note to U.S. Government Users — Documentation related to restricted rights — Use, duplication or disclosure is
subject to restrictions set forth in GSA ADP Schedule Contract with IBM Corp.
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Contents
Preface
The Team That Wrote This Redbook
Comments Welcome
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viii
Chapter 1. The IBM RAMAC Virtual Array
1.1 What Is an IBM RAMAC Virtual Array?
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1.1.1 Overview of RVA and the Virtual Disk Architecture
1.1.2 Log Structured File
1.1.3 Data Compression and Compaction
1.2 VSE/ESA Support for the RVA
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1.2.1 What Is IXFP/SnapShot for VSE/ESA?
1.2.2 What Is SnapShot?
1.2.3 What Is IXFP?
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1.3 What Is Peer-to-Peer Remote Copy?
Chapter 2. RVA Benefits for VSE/ESA
2.1 RVA Simplifies Your Storage Management
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2.1.1 Disk Capacity
2.1.2 Administration
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2.1.3 IXFP
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2.2 Batch Window Improvement
2.2.1 RAMAC Virtual Array
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2.2.2 IXFP/SnapShot for VSE/ESA
2.3 Application Development
2.4 RVA Data Availability
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2.4.1 Hardware
2.4.2 SnapShot
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2.4.3 PPRC
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Chapter 3. VSE/ESA Support for the RVA
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3.1 Prerequisites
3.2 Volumes
3.3 Host Connection
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3.3.1 VSE/ESA Input/Output Configuration Program
3.4 ICKDSF
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3.4.1 Volume Minimal Init
3.4.2 Partial Disk Minimal Init
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Chapter 4. IXFP/SnapShot for VSE/ESA
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4.1 IXFP SNAP
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4.1.1 A Full Volume
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4.1.2 A Range of Cylinders
4.1.3 A Non-VSAM File
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4.2 IXFP DDSR
4.2.1 Expired Files
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4.2.3 A Range of Cylinders
4.2.4 A Specified File
4.3 IXFP REPORT
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4.3.1 Device Detail Report
4.3.2 Device Summary Report
Copyright IBM Corp. 1999
iii
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4.3.3 Subsystem Summary Report
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Chapter 5. Peer-to-Peer Remote Copy
5.1 PPRC and VSE/ESA Software Requirements
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5.2 PPRC Hardware Requirements
5.3 Invoking peer-to-peer remote copy
5.4 SnapShot Considerations
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5.4.1 Primary Devices of a PPRC Pair
5.4.2 Secondary Devices of a PPRC Pair
5.5 Examples of PPRCOPY Commands
5.5.1 Setting Up PPRC Paths and Pairs
5.5.2 Recovering from a Primary Site Failure
5.5.3 Recovering from a Secondary Site Failure
5.5.4 Deleting PPRC Pairs and Paths
5.6 Physical Connections to the RVA
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5.6.1 Determining the Logical Control Unit Number for RVA
5.6.2 Determining the Channel Connection Address
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Appendix A. RVA Functional Device Configuration
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Appendix B. IXFP Command Examples
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B.1 SNAP Command
B.1.1 Syntax
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B.1.2 Using SnapShot to Copy One Volume to Another
B.1.3 Using SnapShot to Copy a File from One Volume to Another
B.1.4 Using SnapShot to Copy Files with Relocation
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B.1.5 Other Uses of SnapShot
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B.2 DDSR Command
B.2.1 Syntax
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B.2.2 Using DDSR to Delete a Single Data Set
B.2.3 Using DDSR to Delete the Contents of a Volume
B.2.4 Using DDSR to Delete the Free Space on an RVA
B.3 Report Command
B.3.1 Syntax
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B.3.2 Reporting on the Capacity of a Single Volume
B.3.3 Reporting on the Capacity of Multiple Volumes
B.3.4 Reporting on the Capacity of the RVA Subsystem
B.4 IXFP/SnapShot Setup Job Streams
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Appendix C. VSE/VSAM Considerations
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C.1 Backing up VSAM Volumes
Appendix D. IOCDS Example
Appendix E. Special Notices
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Appendix F. Related Publications
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F.1 International Technical Support Organization Publications
F.2 Redbooks on CD-ROMs
F.3 Other Publications
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How to Get ITSO Redbooks
IBM Redbook Fax Order Form
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Index
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71
iv RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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ITSO Redbook Evaluation
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73
Contents
v
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vi RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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Preface
This redbook provides a foundation for understanding VSE/ESA′s support for the
IBM 9393 RAMAC Virtual Array (RVA). It covers existing support and the
recently available IXFP/SnapShot for VSE/ESA and peer-to-peer remote copy
support for the RVA. It also covers using IXFP/SnapShot for VSE/ESA for
VSE/VSAM.
The redbook is intended for use by IBM client representatives, IBM technical
specialists, IBM Business Partners, and IBM customers who are planning to
implement IXFP/SnapShot for VSE/ESA on the RVA.
The Team That Wrote This Redbook
This redbook was produced by a team of specialists from around the world
working at the International Technical Support Organization, San Jose Center.
Alison Pate is a project leader in the International Technical Support
Organization, San Jose Center. She joined IBM in the UK after completing an
MSc in Information Technology. A large-systems specialist since 1990, Alison
has eight years of practical experience in using and implementing IBM DASD
solutions. She has acted as a consultant to some of the largest, leading-edge
customers in the United Kingdom—providing technical support and guidance to
their key business projects.
Guenter Rebmann is a DASD HW Support Specialist in Germany. He joined IBM
in 1983 as a Customer Engineer for large system customers. Since 1993 Guenter
has worked in the DASD-EPSG (EMEA Product Support Group) in Mainz,
Germany. His area of expertise is large system hardware products.
Dionisio Dychioco III is a Technical Support Manager in the Philippines. He has
19 years of experience in data processing, including 17 years in technical
support in the IBM mainframe environment. Dionisio has worked at the Far East
Bank & Trust Co. for 12 years. His areas of expertise include MVS, VSE, and
mainframe-PC connectivity.
Bill Worthington is a Consulting IT Technical Specialist in the United States. He
has 38 years of experience in data processing, including 34 years in technical
sales support within IBM. His areas of expertise include high-end disk storage
products as well as VSE/ESA and VM/ESA. Bill has been in his current position
supporting RAMAC DASD products since 1995.
Thanks to the following people for their invaluable contributions to this project:
Janet Anglin, Storage Systems Division, San Jose
Maria Sueli Almeida, International Technical Support Organization, San Jose
Fred Borchers, International Technical Support Organization, Poughkeepsie
Jack Flynn, Storage Systems Division, San Jose
Bob Haimowitz, International Technical Support Organization, Poughkeepsie
Dan Janda, Jr., Advanced Technical Support, Endicott
Teresa Leamon, Storage Systems Division, San Jose
Axel Pieper, VSE Development, Boeblingen, Germany
Hanns-Joachim Uhl, VSE Development, Boeblingen, Germany
Copyright IBM Corp. 1999
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Comments Welcome
Your comments are important to us!
We want our redbooks to be as helpful as possible. Please send us your
comments about this or other redbooks in one of the following ways:
•
Fax the evaluation form found in “ITSO Redbook Evaluation” on page 73 to
the fax number shown on the form.
•
Use the online evaluation form found at http://www.redbooks.ibm.com/
•
Send your comments in an Internet note to [email protected]
viii RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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Chapter 1. The IBM RAMAC Virtual Array
In this chapter we describe the RAMAC Virtual Array (RVA) and the support that
VSE/ESA delivers for it.
1.1 What Is an IBM RAMAC Virtual Array?
We explain functions here on a level that is needed to understand how data is
stored and organized on an RVA. If you would like more detailed descriptions of
this interesting virtual disk architecture, see the redbook entitled IBM RAMAC
Virtual Array, SG24-4951.
1.1.1 Overview of RVA and the Virtual Disk Architecture
Traditional storage subsystems such as the 3990 and 3390 use the count key
data (CKD) architecture. The CKD architecture defines how and where on the
disk device the data is physically stored. Any updates to the data are written
directly to the same position on the physical disk from which the updated data
was read. This is referred to as update in place.
IBM′s RVA provides a high-availability, high-performance storage solution thanks
to its revolutionary virtual disk architecture. To the host, the RVA appears as up
to four traditional 3990 storage controls, with up to 256 3380 or 3390 volumes—64
functional volumes on each 3990. These devices do not physically exist in the
subsystem and are referred to as functional devices. Physically, the subsystem
contains RAID 6-protected arrays of fixed block architecture (FBA) disk devices.
1.1.2 Log Structured File
The RAID-protected FBA disk arrays that make up the RVA′s physical disk space
are sequentially filled with data. New and updated data is placed at the end of
the file, as it is on a sequential or log file. We call this architecture a log
structured file.
Updates leave areas in the log file that are no longer needed. A microcode
process called freespace collection ensures that these areas are put back so that
there is always enough freespace for writing. This process runs as a
background task. You can control the freespace by observing the net capacity
load (NCL) of the RVA and using the IBM Extended Facilities Product (IXFP)
program. See the RVA redbook entitled IBM RAMAC Virtual Array for more
information. The RVA′s physical disk space typically should be kept below 75%
NCL. Above that level, the freespace collection process runs with higher priority,
and performance degradation may result. A service information message (SIM)
informs operators when this threshold is reached.
The following tables are used to map the tracks of functional devices to the FBA
blocks related to those tracks:
•
Functional device table
The functional device table (FDT) holds the information about the functional
volumes that have been defined to the RVA.
•
Functional track directory
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The functional track directory (FTD) is the collective name for two tables that
together map each functional track to an area in the RVA′s physical storage:
−
Functional track table
The functional track table (FTT) contains the host-related pointers, that is,
the functional-device-related track pointers of the FTD.
−
Track number table
The track number table (TNT) contains the back-end data pointers of the
FTD. A reference counter is also part of this table.
Although the FTD consists of two tables, we discuss it as one entity (see
Figure 1). In fact, each functional track has an entry in the FDT. If a functional
track contains data, its associated FTD entry has a pointer to the FBA block
where the data starts. The data of a functional track may fit on one or more FBA
blocks.
If the data of a functional track is updated, the RVA puts the new data in a new
place in the log structured file, and the FTD entry points to the new data location.
There is no update in place.
Figure 1. The RAMAC Virtual Array Tables
1.1.3 Data Compression and Compaction
All data in the RVA is compressed; compression occurs when data enters an
RVA. In addition, the gaps between the records, as they appear on the CKD
devices, are removed before the data is written to disk. Similarly, the unused
space at the end of a track is removed. This is called compaction. The
compression and compaction ratio depends on the nature of the data.
Experience shows that RVA customers can achieve an overall compression and
compaction ratio of 3.6:1.
Data compression speeds up the transfer from and to the arrays. It increases
the effectiveness of cache memory because when compressed more data can fit
in cache.
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1.2 VSE/ESA Support for the RVA
The RVA has been supported by VSE/ESA since its introduction. Because the
RVA presents itself as logical 3380 or 3390 direct access storage devices (DASD)
attached to a logical 3990 Model 3 storage control, releases of VSE/ESA
supporting this logical environment have functioned with the RVA. However,
until now, VSE/ESA has not provided SnapShot, deleted data space release
(DDSR) or capacity reporting natively. It has depended on VM/ESA′s IXFP and
SnapShot to provide that benefit to VSE/ESA guests.
1.2.1 What Is IXFP/SnapShot for VSE/ESA?
IXFP/SnapShot for VSE/ESA is a feature of VSE Central Functions in conjunction
with VSE/ESA Version 2, Release 3.1. It provides SnapShot, DDSR, and capacity
reporting support for the RVA. OS/390 and VM/ESA provide two distinct
products—IXFP and SnapShot—for supporting the RVA, whereas VSE/ESA has
integrated many of the functions provided by these products into a single feature
that implements the support in an Attention Routine command.
1.2.2 What Is SnapShot?
SnapShot, one of the three functions in IXFP/SnapShot for VSE/ESA, enables you
to produce almost instantaneous copies of non-VSAM data sets, volumes, and
data within CYLINDER ranges.
Note: Although not officially supported, VSAM data sets can be indirectly copied
through techniques we discuss in Appendix C, “VSE/VSAM Considerations” on
page 59.
The speed in copying is attained by exploiting the RVA′s virtual disk architecture.
Snapshot produces copies without data movement. We call making a copy with
SnapShot a snap. The result of a SnapShot is also called a snap.
Conventional methods of copying data on DASD consist of making a physical
copy of the data on either DASD or tape. Host processors, channels, tape, and
DASD controllers are involved in these conventional copy processes. Copying
may take a long time, depending on available system resources.
In the RVA′s virtual disk architecture, a functional device is represented by a
certain number of pointers in the FTD. Every used track has a pointer in the FTD
to its back-end data. You snap a copy of the data by copying its FTD pointers.
As you can imagine, snapping is a very fast process that takes seconds rather
than minutes or hours. No data movement takes place, and no additional
back-end physical space is used. Both FTD pointers, the original and the copy,
point to the same physical data location (see Figure 2 on page 4). Notice too
that the TNT entry now has a value of 2, which indicates that the data is in use
by two logical volumes.
Chapter 1. The IBM RAMAC Virtual Array
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3
Figure 2. Data Snapping. SnapShot creates a logical copy by copying the FTD pointers.
Only when either the original or the copied track is updated is its associated FTD
pointer changed to point to the new data location. The other FTD pointer
remains unchanged. Additional space is needed in this case. As long as there
is a pointer to a data block in the physical disk storage, the block cannot become
free for the freespace collection process. A reference counter in the TNT
prevents the block from becoming free.
Although the creation of the copy is a logical manipulation of pointers, the data
exists on disk, so in this sense is not a logical copy. As far as the operating
system is concerned, the two copies are completely independent of each other.
On the RVA hardware side, the snap is a virtual copy of the data.
1.2.3 What Is IXFP?
The IXFP portion of IXFP/SnapShot for VSE/ESA provides two functions: DDSR
and reporting.
1.2.3.1 Deleted Data Space Release
The RVA manages the freespace in the back-end storage by monitoring space
that is no longer occupied by active data. This may be space formerly occupied
by temporary files, such as DFSORT for VSE work files, or it may be space that
previously held data that has been updated and written back to a different array
track in the back-end storage of the RVA. The difference is that the RVA does
not know that the sort work space is no longer needed without being explicitly
told to release it into the free space pool.
The DDSR option of the IXFP operator command provides the ability to release
this freespace back to the RVA. Using DDSR, allocated space can be returned to
the RVA on a subsystem or volume basis. Individual files can also be deleted
and their space returned. DDSR is done using the new IXFP Attention Routine
command when space reclamation is needed. Either the operator can invoke
the commands, or a job stream can include them.
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1.2.3.2 Reporting Functions
The IXFP/SnapShot for VSE/ESA reporting functiion displays logical volume
utilization, such as space allocated and data stored on the volume. It can also
display a summary of the entire subsystem and its NCL, freespace, capacity
allocated and used, and the compression and compaction ratio.
For the capacity management functions supported by OS/390 and VM/ESA, such
as reconfiguring the DASD, adding or deleting volumes, and draining an array,
you use the RVA′s local operator panel.
1.3 What Is Peer-to-Peer Remote Copy?
We explain functions here on a level that is needed to understand how
peer-to-peer remote copy (PPRC) functions on an RVA. If you would like more
detailed descriptions of this data availability architecture, see the RVA redbook
entitled Implementing PPRC on RVA, SG24-4951.
PPRC allows the synchronous copying of data from a primary RVA to one or
more secondary RVAs at the same or a different location while providing
enterprisewide data protection, availability, and ease of system management.
The secondary site may be up to 43 km away from the primary. The
synchronous nature of PPRC offers a full recovery solution while delivering the
highest levels of data integrity and data availability for both operational and
disaster recovery environments.
The availability of PPRC on the RVA Model T82 now places the RVA at the heart
of mission-critical enterprise storage solutions—including remote site disaster
recovery protection, high availability, and data migration capabilities.
Chapter 1. The IBM RAMAC Virtual Array
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Chapter 2. RVA Benefits for VSE/ESA
In this chapter we describe how VSE/ESA′s support for the RVA assists in
managing storage, affects batch window characteristics, improves application
development, and increases the availability of data to the applications running
on the host system.
2.1 RVA Simplifies Your Storage Management
The RVA virtual disk architecture has many benefits to simplify your storage
management. In this section we discuss the improvements in storage
management that the functions and features of the RVA provide.
The space management improvements come from; more effective space use
from compression, minimizing adminstration, and ease of management using
IXFP/SnapShot for VSE/ESA (see Figure 3).
Figure 3. Space Management Improvements
2.1.1 Disk Capacity
The virtual disk architecture and the use of data compression enable you to
store data more effectively in the arrays of the RVA than in a traditional disk
architecture subsystem. The virtual disk architecture reduces the cost per
megabyte in your subsystem and increases the internal transfer rate in the RVA.
There is no allocation of physical disk space for logical volumes, as there is in
traditional subsystems, so unused disk space is not given away. When data is
written to the RVA, the arrays are filled sequentially, independent of the volume
or data set to which the data belongs. The logical capacity that you define is
independent of the physical capacity that you have installed. Therefore you can
define more logical volumes than you would be able to define in a traditional
Copyright IBM Corp. 1999
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disk architecture, for the same physical space. Thus you can spread data over
more volumes to improve performance and data availability of the subsystem.
The hardware design of the RVA allows you to upgrade physical disk space to
726 GB without any subsystem outage time and without any change to the logical
device configuration. Cache upgrades are also concurrent with subsystem
operation. Therefore you have a high level of data availability and low
subsystem outage time for planned configuration changes.
2.1.2 Administration
The subsystem administration activity is reduced for space management. Space
management is simplified with the RVA, because there is no penalty for
overallocation. Data placement activity is also reduced. With the use of the log
structure file, the data from all volumes is spread across all physical disks in the
array. This eliminates the requirement to separate data for availability or
performance reasons, such as preventing high activity data sets, tables, or
indexes from being placed on the same disk volumes.
When the RVA is installed, you can define up to 256 volumes as either 3390 or
3380 devices. This gives you flexibility in your configuration and eases migration
from previous installed hardware. With the virtual disk architecture data
management and tuning activities are minimized. Data is spread across all
disks in the array, automatically balancing the I/O load. When data is updated it
is written to another physical location in the array. As a result uncollected
freespace is created, which the RVA recycles independently in a background
routine to have it available for further use. This automatic freespace collection
keeps the level of the NCL as low as possible without any intervention from
space management, thus reducing the time and cost of storage management.
2.1.3 IXFP
With IXFP it is easy to manage the subsystem and monitor the NCL. With the
use of IXFP SnapShot, the time expended to copy volumes, data sets, or files is
considerably reduced. Backups can be done more often to increase the
consistency and data availability of your system.
The IXFP reporting function provides information about the space utilization of a
single RVA device or range of RVA devices. With the DDSR function of IXFP you
can release expired files residing on all VSE-managed RVA volumes whose
expiration date has been reached. You can process a complete volume, a
cylinder range, or a specified file. Thus the RVA can manage subsystem
freespace more efficiently than before.
2.2 Batch Window Improvement
Reducing the batch processing time increases the availability of online
applications. RVA and IXFP/SnapShot for VSE/ESA help reduce batch processing
time in several areas.
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2.2.1 RAMAC Virtual Array
The RVA′s virtual disk architecture enables performance improvement in batch
processing. This new architecture, coupled with data compression and
self-tuning capabilities, improves disk capacity utilization. Data from all logical
volumes is written across all the physical disks the array. Automatic load
balancing across the volumes occurs as data is written to the array. Further, the
ability of the RVA to dynamically configure additional volumes of various sizes
eliminates volume contention and thereby reduces I/O bottlenecks.
In the RVA, space that has never been allocated or is allocated but unused takes
up no capacity. Data set size can increase and new files can be created with
minimal need to reorganize existing stored data. Users of traditional storage
systems keep lots of available free space to avoid batch application failures,
wasting valuable space and increasing storage costs. With the RVA it is not
necessary to keep lots of free space to avoid out-of-space conditions.
2.2.2 IXFP/SnapShot for VSE/ESA
Based on the belief that the best I/O is no I/O, IXFP/SnapShot for VSE/ESA
reduces online system outage by reducing the amount of elapsed time backups
and copies need to complete. IXFP/SnapShot for VSE/ESA improves these
aspects of batch processing:
•
Data backup
Data is backed up during batch processing for many different reasons.
Copying data to protect against a hardware, software, or application failure
in the computer center is considered an operational backup. The backup
might be a complete copy of all data, or an incremental copy, that is, a
backup of the changes made since the last backup.
Data backups can be taken between processing steps to protect against data
loss if a subsequent job or step fails. These backups are called interim
backups. In some data centers, interim backups are done with tapes.
Using SnapShot to replace the backup and/or copy operations speeds up
processing. Tapes are no longer required, and interim backups are done
more quickly. Additional interim backup points are now possible because of
the instantaneous copy capability and reduced batch processing time. The
interim backups are deleted after successful completion of the batch
process.
In many cases the operational backups made are also used for disaster
recovery. Many of the considerations for disaster recovery are also valid for
operational backup. You can minimize the time for disaster backups using
SnapShot, by making a SnapShot copy to disk. You can then restart online
applications before making a tape backup of the SnapShot copy.
•
Data set reorganization
Data set reorganization is very often a time-consuming part of nightly batch
processing. The REORG becomes important especially when it is part of the
critical path of batch processing. Traditional reorganization procedures copy
the affected VSAM key-sequenced data set (KSDS) into a sequential data set
on tape or on another DASD. This activity takes a long time when large data
sets are copied. SnapShot can dramatically reduce the run time when used
in place of IDCAMS REPRO to copy the KSDS into a sequential data set on
another DASD.
Chapter 2. RVA Benefits for VSE/ESA
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9
•
Report generation
A large part of batch processing is often dedicated to generating output
reports from production data. Often read access only is required by the
applications. SnapShot can be used to decrease the contention of multiple
read jobs accessing the same data set by replicating critical files and
allowing parallel access to multiple copies of the data.
•
•
Production problem resolution
You can use SnapShot to create a copy of the production database when you
need to simulate and resolve problem conditions in production. This
reduces disruption to the production environment as it is possible to snap
complete copies of the production database in a very short time.
Application processing
SnapShot can be used to speed up any data copy steps during batch
processing.
2.3 Application Development
In the area of application development, the RVA and IXFP/SnapShot for VSE/ESA
provide dynamic volume configuration and rapid data duplication.
•
Dynamic volume configuration
Additional volumes can be easily created if and when required. Using the
RVA local operator panel and device address predefinition in the VSE I/O
Configuration Program (IOCP), you can dynamically create or remove
volumes. You can easily add volumes required to simulate the production
environment. Temporary scratch volumes needed as work areas or testing
areas can be easily created. Production volumes can be cloned to re-create
and resolve a problem.
•
Data duplication (including Year 2000)
Several copies of test databases can be easily produced for several testing
units to use at the same time, for example, maintenance, user acceptance
testing, and enhancements. After a test cycle the test database can be reset
by resnapping from the original with SnapShot. Year 2000 testing requires
several iterations, to verify code changes with a new date. You can snap
your existing production database to create a new test database.
2.4 RVA Data Availability
The design and concept of the RVA are predicated on a very high level of data
availability. In this section we discuss the components, functions, and features
that guarantee and improve the data availability of the RVA.
2.4.1 Hardware
The RVA hardware is based on an N+1 concept. All functional areas in the
machine are duplicated. If one of these areas becomes inoperable because of a
hardware problem, other parts of the machine can take over its functions,
without losing data availability. In most cases there is no significant
performance degradation.
The disk arrays have two spare drives. If a drive fails, the data is immediately
reconstructed on one of the spare drives, and the broken drive is fenced. During
this process data availability is maintained without performance degradation.
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All necessary repair actions due to a hardware failure are performed
concurrently with customer operation.
With the RVA, data availability is also maintained during upgrades. Upgrading
disk arrays or cache size can be done concurrently with subsystem operation,
without impact or performance degradation.
2.4.2 SnapShot
2.4.3 PPRC
With SnapShot you can make a copy of your online data to use for different tests
while the original data is available to the production system. In the same way,
you can use a SnapShot copy to back up volumes to tape or other media while
online applications continue to have access to the original data.
PPRC provides a synchronous copying capability for protection against loss of
access to data in the event of an outage at the primary site. Whenever a
disaster occurs at the primary site and the data there is no longer available, you
can switch to the secondary site. The switch is nearly without impact to or
outage of your operating system, and all data is again available with minimal
effort.
Chapter 2. RVA Benefits for VSE/ESA 11
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Chapter 3. VSE/ESA Support for the RVA
In this chapter we cover several utilities and the VSE/ESA Base Programs that
support the RVA.
3.1 Prerequisites
The RVA has been supported since VSE/ESA Version 1.4 and RVA microcode
level of LIC 03.00.00 or higher. An equivalent microcode level is required for the
StorageTek Iceberg 9200.
To use IXFP/SnapShot and PPRC for VSE/ESA (see Chapter 4, “IXFP/SnapShot
for VSE/ESA” on page 17 and Chapter 5, “Peer-to-Peer Remote Copy” on
page 33) the prerequisites are different from the basic RVA support. The
requirements for IXFP/SnapShot for VSE/ESA support are:
•
RAMAC Virtual Array Licensed Internal Code (LIC) 04.03.00 or higher. An
equivalent microcode level is required for the StorageTek Iceberg 9200.
Note: LIC level 03.02.00 contains support for SnapShot. However, level
04.03.00 introduced nondisruptive code load for the RVA′s microcode and is
the recommended minimum level.
•
VSE/ESA 2.3.0 (5690-VSE) installed with VSE/AF Supervisor with PTF DY44820
or higher.
•
SnapShot requires Feature 6001 for existing 9393 systems or RPQ 8S0421 for
StorageTek Icebergs.
•
If IXFP/SnapShot for VSE/ESA is used in a VM/VSE environment, VM APAR
VM61486 is required for minidisk cache (MDC) support.
For PPRC, the requirements are discussed in 5.1, “PPRC and VSE/ESA Software
Requirements” on page 34 and 5.2, “PPRC Hardware Requirements” on
page 35.
The RVA subsystem provides a set of control and monitoring functions that
extend the set of IBM 3990 control functions. Many of these functions can be
invoked either from the host with the IXFP/SnapShot for VSE/ESA or directly from
the RVA. The Extended Control and Monitoring (ECAM) interface is the protocol
for communications between the host CPU and the RVA. The use of the ECAM
interface is generally transparent to the user.
These functions require that APAR DY44820 be installed and the phase $IJBIXFP
has been loaded to the SVA via the SET SDL interface. Once the phase has
loaded, any of above functions can be invoked through simple operator
commands.
If you want to enable SnapShot on a StorageTek 9200, you must submit an RPQ
to IBM for each serial number.
Before you use IXFP/SnapShot or PPRC for the RVA, we recommend checking
with your local IBM support center to get information about the latest levels of
VSE/ESA, microcode, and required APARs.
Copyright IBM Corp. 1999
13
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3.2 Volumes
With VSE/ESA and the RVA, the subsystem volumes can be defined in different
emulation modes. This makes the RVA absolutely adaptable to your needs.
The following device type emulations are supported with the RVA:
•
3380 model J, K, and KE (KE is a 3380K compatible device with the same
number of cylinders (1770) as a 3380E).
•
3390 models 1, 2, and 3
3.3 Host Connection
Host connectivity options include parallel and/or ESCON attachment. Extended
connectivity parallel channel configurations of up to 32 channels are available
and supported without bus and tag output connections. The bus and tag outputs
are internally terminated, so the RVA must physically be the last in a
daisy-chained configuration. ESCON configurations include up to 128 logical
links, either as direct links or through an ESCON Director.
The physical channel configuration must match the definitions in the I/O
configuration data set (IOCDS). The physical connections on the CPU and the
RVA must reflect the statements in the IOCDS. Mistakes can go undetected until
later maintenance actions cause unnecessary impact. The channel configuration
should be planned such that the impact of a single component failure is
minimized. For an IOCDS example, refer to Appendix D, “IOCDS Example” on
page 63.
3.3.1 VSE/ESA Input/Output Configuration Program
Support for the stand-alone IOCP is supplied with the hardware system′s service
processor or processor controller. IOCP describes a system′s I/O configuration
to the CPU.
Before you install VSE/ESA natively (not under VM/ESA or an LPAR), make sure
that you have fully configured your system through IOCP. Starting with VSE/ESA
1.3, the VSE/ESA IOCP is automatically installed during initial installation of
VSE/ESA. You can use the IOCP batch program to create a new IOCDS when
you change the hardware configuration. You can use the IOCP batch program to
define and validate the IOCP macro instructions if you prepare for the installation
of a new processor. Use skeleton SKIOCPCN (available in VSE/ICCF library 59)
as a base for configuration changes.
An IOCDS must be generated for the hardware the first time through the
stand-alone IOCP delivered with the processor. For this program you can use
prepared IOCP macro instructions that have been generated on another
processor. The specified device numbers for VSE/ESA must be within the range
0000 through 0FFF. The devices themselves can be attached to any available
link.
For more information about IOCP, refer to the processor′s IOCP manual and to
the IOCP User′s Guide and ESCON Channel-to-Channel Reference, GC38-0401.
14 RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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3.4 ICKDSF
Once the 9393 is installed and the functional devices are defined on the operator
panel (see Appendix A, “RVA Functional Device Configuration” on page 41) the
only initialization needed for the RVA functional devices is a minimal init,
ICKDSF INIT, with the additional parameters needed to define the VOLID and the
volume table of contents (VTOC) size and location. The CHECK parameter is not
supported, because surface checking is not needed on an RVA. Other ICKDSF
functions for surface checking, such as INSTALL or REVALIDATE, also are not
supported for the RVA.
The RVA internally uses FBA disk drives with internal data error recovery, so
surface checking in this way is inappropriate. If a media surface check is
needed, the IBM service representative can do this on the maintenance panel.
ICKDSF Release 16 with applicable PTFs is needed to support the RVA. To run
the VSE version of ICKDSF in batch mode, submit a job with an EXEC ICKDSF job
control statement.
3.4.1 Volume Minimal Init
In the example in Figure 4 a volume is initialized at minimal level under VSE. A
VSE format VTOC is written at cylinder 32, track 0 for a length of 20 tracks. The
volume is labeled 338001.
// JOB
// ASSGN
// EXEC
jobname
SYS002,151
ICKDSF,SIZE=AUTO
INIT SYSNAME(SYS002) NOVERIFY -
VSEVTOC(X′20′, X′ 0′ , X′14′) VOLID(338001)
/*
/&
Figure 4. ICKDSF INIT Volume at the Minimal Level
3.4.2 Partial Disk Minimal Init
In the example in Figure 5, an emulated partial disk is initialized under VSE. A
VSE format VTOC is written at cylinder 0, track 1 for a length of one track. The
volume is labeled AA3380.
// JOB
// ASSGN
// EXEC
jobname
SYS000,353
ICKDSF,SIZE=AUTO
INIT SYSNAME(SYS000) NVFY VSEVTOC(0,1,1) -
VOLID(AA3380) MIMIC(EMU(20))
/*
/&
Figure 5. ICKDSF INIT Emulated Partial Disk
For more information about and examples of running ICKDSF under VSE, refer to
the ICKDSF R16 User′s Guide, GC35-0033.
Chapter 3. VSE/ESA Support for the RVA 15
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Chapter 4. IXFP/SnapShot for VSE/ESA
IXFP/SnapShot for VSE/ESA is a combination of software and RVA microcode
functions. It has three main functions, namely, SnapShot, DDSR, and Report.
SnapShot is the data duplication utility that exploits the RVA′s virtual disk
architecture to achieve instantaneous copy without actually using resources.
DDSR releases space occupied by a volume, a cylinder range, and a specified
data set. The report functions provide information about the space utilization
and subsystem utilization summary of the RVA.
A new attention routine ($IJBIXFP) has been provided in VSE. You invoke
IXFP/SnapShot for VSE/ESA functions through the attention routine in three basic
ways:
1. From a console
You enter the IXFP/SnapShot for VSE/ESA functions on the command line of
the VSE operator console or through the interactive computing and control
facility (ICCF) console operator interface.
Note: Make sure that you are authorized to enter operator commands when
using the ICCF console operator interface.
Figure 6 illustrates invoking IXFP REPORT functions directly from the
operator console.
ꢀSYSTEM : VSE/ESA
ꢁ
VSE/ESA 2.3
USER :
TIME :
AR 0015 1I40I READY
-------------------------------------------------------------------------
ꢂ==> IXFP REPORT<enter>
ꢃ
Figure 6. Sample Operator Console Screen to Invoke IXFP REPORT Functions
Copyright IBM Corp. 1999
17
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2. From a batch job
You can code the function you want to invoke in the PARM field of the
VSE-provided DTRIATTN module and submit the batch job for execution.
Figure 7 illustrates the report function (IXFP REPORT) being invoked by a
batch job using DTRIATTN.
// JOB
// log
// EXEC
/&
jobname
DTRIATTN,PARM=′ IXFP REPORT′
Figure 7. Sample Batch Job to Invoke IXFP Report Function
3. From a REXX CLIST
You can code the IXFP function in the SENDCMD of REXX. Use of a REXX
CLIST allows use of logic for automated procedures. Figure 8 shows the
statements required to catalog the REXX procedure. Figure 9 on page 19
illustrates invoking the report function (IXFP REPORT) from a REXX CLIST in
a batch job. The second SENDCMD in the job is a dummy. It is coded to
illustrate the possibility of coding other IXFP/SnapShot for VSE/ESA or VSE
commands, thus providing flexibility for creating automated procedures.
* $$ JOB JNM=IXFPREXC,CLASS=0,DISP=D
// JOB IXFPREXC
// EXEC LIBR
ACC S=PRD2.CONFIG
CAT IXFPREXX.PROC R=Y
/* -=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=- */
/*
REXX/VSE procedure to issue console commands
*/
/* -=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=- */
trace off
arg parm_string
parse var parm_string command1 ′#′ command2
rc = SENDCMD( command1 )
if rc = 0
then do
call sleep 5
rc = SENDCMD( command2 )
end
/* Submit first command
*/
/* Wait before submitting next command */
/* Submit second command */
exit rc
/+
/*
/&
* $$ EOJ
Figure 8. Cataloging a REXX CLIST Procedure to Invoke an IXFP Function
18 RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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* $$ JOB JNM=IXFPREXX,CLASS=0,DISP=D
// JOB IXFPREXX
// LIBDEF *,SEARCH=(PRD2.CONFIG,PRD1.BASE)
// EXEC REXX=IXFPREXX,PARM=′ IXFP REPORT#<your-console-cmd-2>′
/&
* $$ EOJ
Figure 9. Using a REXX CLIST As a Batch Job Step to Invoke an IXFP Function
Note: More information about the REXX/VSE console automation capability
can be found in Chapter 14 of the REXX/VSE V6 R1.2 Reference Manual,
SC33-6642-01.
Chapter 4. IXFP/SnapShot for VSE/ESA 19
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Figure 10 displays the RVA subsystem status on the operator console.
ꢀixfp report
ꢁ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
AR 0015
DETAIL REPORT ***
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80E 2838.0 N/A
AR 0015 80F 2838.0 N/A
AR 0015
AR 0015 *** DEVICE
AR 0015 CAPACITY
369.2 2468.7 N/A
0.8 2837.1 N/A
13.01 86.99 213.6
0.03 99.97 0.0
1.72
9.65
SUMMARY REPORT
<-----TOTAL-----> <------TOTALS %------>
5676.032 MB 100.00
COMP.
RATIO
AR 0015
AR 0015
AR 0015
AR 0015
AR 0015
DEFINED
STORED
PHYS.USED
UNUSED
370.129 MB
213.688 MB
5305.903 MB
6.52
3.76
1.73
93.48
AR 0015 *** SUBSYSTEM SUMMARY REPORT ***
AR 0015 SYSTEM
AR 0015 PROD
AR 0015
DEFINED-CAPACITY
726532.208 MB
DISK-ARRAY-CAP FREE-DISK-ARRAY-CAP
117880.209 MB 57752.311 MB
AR 0015 NET-CAPACITY-LOAD(%) COLL.-FREE-SPACE(%) UNCOLL-FREE-SPACE(%)
AR 0015 TEST PROD OVERALL TEST PROD OVERALL TEST PROD OVERALL
AR 0015 0.00 51.01 51.01
0.00 47.55 47.55 0.00 1.44
1.44
ꢂAR 0015 1I40I READY
ꢃ
Figure 10. Sample Console Output of the IXFP REPORT Function
Figure 11 shows the general syntax of the IXFP command.
┌─,───────────────────────────────────────────────────────────────┐
ꢁ
ꢀꢀ──IXFP──┬─SNAP,─┬──source─┬───────────────────┬─:target─┬────────┬──┬─────────────┬─┴─┬──┬───────────┬──┬─────────ꢀꢂ
│
│
│
│
│
│
└─(scyl─┬─-scyl─┬─)─┘
└─.ncyl─┘
└─(tcyl)─┘ └─,VOL1=volid─┘ │ └─,NOPROMPT─┘ │
│
│
│
│
└─source(DSN=′ data-set-name′ ) : target─┬────────┬───────────────────────┘
└─(tcyl)─┘
├─DDSR─┬────────────────────────────────┬──┬───────────┬────────────────────────────────────────┤
│
│
│
│
│
│
│ ┌────────────────────────────┐ │ └─,NOPROMPT─┘
│
│
│
│
│
│
ꢁ
├──,unit─┬───────────────────┬─┴─┤
│
│
└─(dcyl─┬─-dcyl─┬─)─┘
└─.ncyl─┘
│
│
└─,unit(DSN=′ data-set-name′ ) ─────┘
┌───────┐
ꢁ
└─REPORT──┬─────┬┴──────────────────────────────────────────────────────────────────────────────┘
└─,id─┘
Figure 11. General Syntax of IXFP Command
See Appendix B, “IXFP Command Examples” on page 43 for an explanation of
the IXFP specifications.
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4.1 IXFP SNAP
SNAP identifies this command as a SNAP function. Figure 12 shows the syntax
of the IXFP SNAP command.
┌─,───────────────────────────────────────────────────────────────┐
ꢁ
ꢀꢀ──IXFP────SNAP,─┬──source─┬───────────────────┬─:target─┬────────┬──┬─────────────┬─┴─┬──┬───────────┬────────────ꢀꢂ
│
│
└─(scyl─┬─-scyl─┬─)─┘
└─.ncyl─┘
└─(tcyl)─┘ └─,VOL1=volid─┘ │ └─,NOPROMPT─┘
│
└─source(DSN=′ data-set-name′ ) : target─┬────────┬───────────────────────┘
└─(tcyl)─┘
Figure 12. Syntax of IXFP SNAP Command
Note: SnapShot commands can be set up to be invoked by end users as well as
by database administrators and system programmers.
There are three ways to do a SnapShot. You can take a copy of:
•
A full volume
•
A range of cylinders
•
A non-VSAM file
4.1.1 A Full Volume
You copy a full volume by identifying the device address (cuu) or VOLID label of
the source and target in the IXFP SNAP command. Intermixing of the device
address and VOLID label to specify the source and target in the IXFP command
is allowed. Use the VOL1= parameter to specify the volume label that the
target will assume after the copy has completed. If the VOL1= parameter is
omitted, the source and target volumes will have the same VOLID label when the
copy is completed.
To illustrate, we use two volumes: PATEV1 and PATEV2. The device addresses
of these volumes are 80E and 80F, respectively. To copy the first volume onto
the second volume, issue any of the following commands:
•
IXFP SNAP,80E:80F,NOPROMPT
•
IXFP SNAP,PATEV1:PATEV2,NOPROMPT
•
IXFP SNAP,PATEV1:80F,NOPROMPT
In this case the source 80E and target 80F will have the same VOLID label
(PATEV1) after the snap completes. A VOL1= parameter can be used to give
the target a specific VOLID label after the snap of the source volume. Continuing
with the example, to give the target volume a VOLID label of PATEV3, we include
a VOL1= parameter indicating VOLID label PATEV3. Use one of the following
commands;
•
IXFP SNAP,80E:80F,VOL1=PATEV3,NOPROMPT
•
IXFP SNAP,PATEV1:80F,VOL1=PATEV3,NOPROMPT
The NOPROMPT parameter is included to prevent decision-type messages from
being issued. Otherwise, decision-type messages are issued for the operator to
verify and confirm (see Figure 13 on page 22).
Chapter 4. IXFP/SnapShot for VSE/ESA 21
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ꢀAR 0015 1I40I READY
ꢁ
ꢃ
ixfp snap,80e:80f,vol1=patev3
AR+0015 IXFP23D SNAP FROM CUU=80E CYL=′0000′ TO CUU=80F CYL=′0000′ NCYL=′0D0B
- REPLY ′ YES′ TO PROCEED
15 yes
AR 0015 IXFP22I SNAP TO CUU= 80F STARTED AT 18:46:51 11/16/1998
AR 0015 IXFP20I SNAP FUNCTION COMPLETED AT 18:46:51 11/16/1998
ꢂAR 0015 1I40I READY
Figure 13. Decision-Type Message Issued to Confirm SNAP
VSE/VSAM
VSE/VSAM support is not currently included in IXFP/SnapShot for VSE/ESA.
However, you can still take advantage of IXFP/SnapShot for VSE/ESA with
VSE/VSAM data sets. With volume snap, VSAM data sets can be indirectly
copied when the VSAM catalog, space, and cluster are in the same volume.
In VSE, you can reference the two USER CATALOGs individually through the
use of the ASSGN JCL statement; however, the VSAM share option
restrictions still apply. The ideal scenario is to assign the target volume into
another LPAR so as not to encounter the restrictions and further processing
or copy to tape using IDCAMS REPRO. If the purpose of the volume snap is
for backup using FASTCOPY or DDR (VM), the VSAM share option
restrictions will not be encountered.
See Appendix C, “VSE/VSAM Considerations” on page 59.
Notes:
If the source is identified by its VOLID, it must be either the only volume with
that VOLID or the only VOLUME with that VOLID that is up (DVCUP).
Otherwise an error message will be issued.
The target device must be down (DVCDN) before you initiate the volume
snap.
If the target device is identified by its VOLID, it must be either the only
volume with that VOLID or the only volume with that VOLID which is down
(DVCDN). Otherwise an error message will be issued.
Only when doing full volume snaps can you use the VOL1 parameter.
Volume copying is done unconditionally within the specified or assumed
boundaries. VSE does not perform any VTOC checking on the specified
target device and thus does not provide any warning messages regarding
overlapping extents or secured or unexpired files.
When you duplicate a volume, both the source and the target must be within
the same RVA. (If you are using test partitions, the source and the target
must also be in the same partition.)
22 RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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4.1.2 A Range of Cylinders
You copy a range of cylinders by identifying the device address or VOL1 label of
the source and target in the IXFP SNAP command. In addition, the decimal start
cylinder (scyl) and end cylinder (-scyl) or number of cylinders (,ncyl) are
specified in parentheses and appended to the source specification. Optionally,
the target start cylinder (tcyl) can be included to specify where copying is to start
on the target device.
To illustrate, we use two volumes: PATEV1 and PATEV2. The device addresses
of these volumes are 80E and 80F, respectively. To copy cylinders 0 through 999
in the first volume onto the second volume, issue one of the following
commands:
•
IXFP SNAP,80E(0000-0999):80F,NOPROMPT
•
IXFP SNAP,80E(0000,1000):80F,NOPROMPT
•
IXFP SNAP,PATEV1(0000-0999):PATEV2,NOPROMPT
•
IXFP SNAP,PATEV1(0000,1000):PATEV2,NOPROMPT
You specify the target start-cylinder (tcyl) to relocate the range of cylinders on
the target volume. Indicate target start-cylinder 1000 to relocate the range of
cylinders on the target volume. You can issue one of the following modified
commands:
•
IXFP SNAP,80E(0000-0999):80F(1000),NOPROMPT
•
IXFP SNAP,80E(0000,1000):80F(1000),NOPROMPT
•
IXFP SNAP,PATEV1(0000-0999):PATEV2(1000),NOPROMPT
•
IXFP SNAP,PATEV1(0000,1000):PATEV2(1000),NOPROMPT
You may or may not include the NOPROMPT parameter to prevent or allow
decision-type messages (see Figure 13 on page 22).
Notes:
If the source is identified by its VOLID, it must be either the only volume with
that VOLID or the only VOLUME with that VOLID which is up (DVCUP).
Otherwise an error message will be issued.
The target device must be down (DVCDN) before you initiate the volume
snap, except when the source and the target device are the same device.
If the target device is identified by its VOLID, it must be either the only
volume with that VOLID or the only volume with that VOLID which is down
(DVCDN). Otherwise an error message will be issued.
The highest (end) cylinder number must not exceed 32767 or the maximum
number of cylinders of the devices. The start cylinder number must not be
greater than the end cylinder number.
You cannot use the VOL1 parameter when copying cylinder ranges.
Cylinder range copying is done unconditionally within the specified or
assumed boundaries. VSE does not perform any VTOC checking on the
specified target device and thus does not provide any warning messages
regarding overlapping extents or secured or unexpired files.
Chapter 4. IXFP/SnapShot for VSE/ESA 23
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The source and the target device must be of the same type and must be
within the same RVA subsystem. (If you are using test partitions, the source
and the target must also be in the same partition.)
4.1.3 A Non-VSAM File
You copy a file by indicating the data set name on the source device, using the
DSN= (data set name) parameter, in addition to identifying the source and
target device address or VOLID labels. The file specified must be non-VSAM.
Optionally, the target start cylinder (tcyl) can be included to specify where
copying is to start on the target device if relocation is required.
To illustrate, we use two volumes: PATEV1 and PATEV2. The device addresses
of these volumes are 80E and 80F, respectively. To copy file ′test.data.1′ in
volume 80E onto volume 80F, issue one of the following commands:
•
IXFP SNAP,80E(DSN=′ test.data.1′): 80F,NOPROMPT
•
IXFP SNAP,PATEV1(DSN=′ test.data.1′): 80F,NOPROMPT
If you want to copy file ′test.data.1′ to cylinder 1000 on volume 80F, you must
specify the target start cylinder (tcyl). Issue one of the following modified
commands:
•
IXFP SNAP,80E(DSN=′ test.data.1′): 80F(1000),NOPROMPT
•
IXFP SNAP,80E(DSN=′ test.data.1′ ) : PATEV2(1000),NOPROMPT
Notes:
If source is identified by its VOLID, it must be either the only volume with
that VOLID or the only VOLUME with that VOLID that is up (DVCUP).
Otherwise an error message will be issued.
The target device must be down (DVCDN) before you initiate the volume
snap, except when the source and the target are the same device.
If the target device is identified by its VOLID, it must be either the only
volume with that VOLID or the only volume with that VOLID that is down
(DVCDN). Otherwise an error message will be issued.
The highest (end) cylinder number must not exceed 32767 or the maximum
number of cylinders of the devices. The start cylinder number must not be
greater than the end cylinder number.
You cannot use the VOL1 parameter when copying a non-VSAM file.
When you snap files, VSE performs VTOC checking on the specified target
device and provides warning messages regarding overlapping extents or
secured or unexpired files.
The source and the target device must be of the same type and must be
within the same RVA subsystem. (If you are using test partitions, the source
and the target must also be in the same partition.)
See B.1, “SNAP Command” on page 43 for additional illustrations.
24 RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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4.2 IXFP DDSR
DDSR identifies this command as a DDSR function. DDSR causes the release of
the physical storage space associated with:
•
Expired files
•
A total volume
•
A range of cylinders
•
A specified file
This function ensures that all space releases done on the VSE system (normally
through deletes) result in space releases in the RVA subsystem. Figure 14
shows the syntax of the IXFP DDSR command.
ꢀꢀ──IXFP────DDSR─┬────────────────────────────────┬──┬───────────┬──────────────────────────────────────────────────ꢀꢂ
│ ┌────────────────────────────┐ │ └─,NOPROMPT─┘
ꢁ
├──,unit─┬───────────────────┬─┴─┤
│
│
└─(dcyl─┬─-dcyl─┬─)─┘
└─.ncyl─┘
│
│
└─,unit(DSN=′ data-set-name′ ) ─────┘
Figure 14. Syntax of IXFP DDSR Command
4.2.1 Expired Files
DDSR, when specified without any additional parameters, deletes the VTOC
entries and all physical space for all expired nonsecured files residing on VSE
managed RVA devices. These extents are freed up and become part of free
space.
To illustrate, we use two volumes: PATEV1 and PATEV3. The device addresses
of these volumes are 80E and 80F, respectively. To delete all VSE-recognized
expired files, issue the following command:
IXFP DDSR,NOPROMPT
The NOPROMPT parameter is included to prevent decision-type messages from
being issued. Otherwise, decision-type messages are issued for the operator to
verify and confirm (see Figure 15).
ꢀAR 0015 1I40I READY
ꢁ
IXFP DDSR
AR+0015 IXFP26D ′ TEST.DATA.1′ HAS EXPIRED ON CUU=80E - REPLY ′ YES′ FOR DELETION
15 YES
AR+0015 IXFP26D ′ TEST.DATA.1′ HAS EXPIRED ON CUU=80F - REPLY ′ YES′ FOR DELETION
15 YES
ꢂAR 0015 1I40I READY
ꢃ
Figure 15. Decision-Type Message Issued to Confirm DDSR Expired Files
Chapter 4. IXFP/SnapShot for VSE/ESA 25
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Notes:
When you do DDSR for expired files, VSE performs checking on the online
(up) units.
DDSR checks only those RVA devices managed by the VSE system.
DDSR considers only the files created by VSE.
4.2.2 A Total Volume
It is possible to delete and release space for an entire volume when you include
the device address or VOLID label with no other operands.
To illustrate, we use volume PATEV3 with device address 80F. To delete all data
including the VTOC and VOLID label of PATEV3, issue the following command:
IXFP DDSR,PATEV3
The NOPROMPT parameter is included to prevent decision-type messages from
being issued. Otherwise, decision-type messages are issued for the operator to
verify and confirm (see Figure 16).
ꢀAR 0015 1I40I READY
ꢁ
IXFP DDSR,PATEV3
AR+0015 IXFP29D DDSR FOR CUU=80F (WHOLE VOLUME) - REPLY ′ YES′ FOR DELETION
15 YES
ꢂAR 0015 1I40I READY
ꢃ
Figure 16. Decision-Type Message Issued to Confirm DDSR Volume
Notes:
The device should belong to the RVA subsystem managed by the VSE
system.
The device should be in the offline (DVCDN) condition.
The device should be reinitialized before you use it as a regular volume
again. However, if you are going to use it as a target for a volume snap, you
can leave it as is.
4.2.3 A Range of Cylinders
This command is similar to the DDSR volume command, except that additional
specifications are added to signify the decimal start cylinder and end cylinder
(dcyl-dcyl) or the decimal start cylinder and the number of cylinders (dcyl,ncyl) to
delete.
To illustrate, we use volume PATEV3 with device address 80F. To delete all data
from cylinders 0 through cylinder 999, issue the following command:
IXFP DDSR,PATEV3(0000-0999),NOPROMPT
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The NOPROMPT parameter is included to prevent decision-type messages from
being issued. Otherwise, decision-type messages are issued for the operator to
verify and confirm (similar to Figure 16).
Notes:
The device should belong to the RVA subsystem managed by the VSE
system.
The device should be in the offline (DVCDN) condition.
The highest (end) cylinder number must not exceed 32767 or the maximum
number of cylinders of the devices. The start cylinder number must not be
greater than the end cylinder number.
4.2.4 A Specified File
This command is similar to doing DDSR for a specific range of cylinders. The
difference is that a DSN= specification is coded in place of the decimal start
cylinder and decimal end cylinder (dcyl-dcyl).
To illustrate, we use volume PATEV3 with device address 80F. To delete file
′test.data.3′ on volume PATEV3, issue the following command:
IXFP DDSR,PATEV3(DSN=′ test.data.3′ ) , NOPROMPT
The NOPROMPT parameter is included to prevent decision-type messages from
being issued. Otherwise, decision-type messages are issued for the operator to
verify and confirm (similar to Figure 16 on page 26).
Notes:
The device should belong to the RVA subsystem managed by the VSE
system.
The device should be in the online (DVCUP) condition. Otherwise the
command is rejected, and an error message is displayed.
The file must be non-VSAM.
The file will be deleted unconditionally and the space returned to the RVA
freespace.
When you process multivolume files, repeat DDSR for all volumes containing
the file extents.
See B.2, “DDSR Command” on page 49 for additional illustrations.
4.3 IXFP REPORT
The IXFP REPORT command provides information about the space utilization of a
single RVA device or a range of RVA devices. It also provides information about
the space utilization of all devices (that were added during IPL) of an RVA
subsystem as well as important subsystem utilization summary information.
Figure 17 on page 28 shows the syntax of the IXFP REPORT command.
Chapter 4. IXFP/SnapShot for VSE/ESA 27
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┌───────┐
ꢁ
ꢀꢀ──IXFP────REPORT──┬─────┬┴────────────────────────────────────────────────────────────────────────────────────────ꢀꢂ
└─,id─┘
Figure 17. Syntax of IXFP REPORT Command
When the command is issued without the id parameter, all information about
every RVA subsystem, including all devices known to the VSE system, is
displayed.
If you need information about a specific device, a specific range of devices, or a
specific RVA subsystem, include the id parameter to limit the scope of the report
output.
To illustrate, we use two volumes: PATEV1 and PATEV2. The device addresses
of these volumes are 80E and 80F, respectively. To display space utilization for
one of the devices, issue one of the following commands:
•
IXFP REPORT,80E
•
IXFP REPORT,80F
It is also possible to display the space utilization of the two devices in one
command by including the addresses of the two devices. Issue the following
command:
IXFP REPORT,80E,80F
To get all space information for the entire VSE system, issue the command
without any additional parameter:
IXFP REPORT
Notes:
The device must belong to the RVA subsystem managed by the VSE system.
If used under VM, REPORT only works for full-pack minidisks or dedicated
devices.
NOPROMPT is not a valid parameter for IXFP REPORT.
Issuing IXFP REPORT or IXFP REPORT,80 yields the same result because we
are only using one RVA subsystem and there is only one device address
range (80).
Figure 18 on page 29 shows a sample IXFP REPORT output.
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ꢀixfp report
ꢁ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
AR 0015
DETAIL REPORT ***
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80E 2838.0 N/A
AR 0015 80F 2838.0 N/A
AR 0015
AR 0015 *** DEVICE
AR 0015 CAPACITY
369.2 2468.7 N/A
0.8 2837.1 N/A
13.01 86.99 213.6
0.03 99.97 0.0
1.72
9.65
SUMMARY REPORT
<-----TOTAL-----> <------TOTALS %------>
5676.032 MB 100.00
COMP.
RATIO
AR 0015
AR 0015
AR 0015
AR 0015
AR 0015
DEFINED
STORED
PHYS.USED
UNUSED
370.129 MB
213.688 MB
5305.903 MB
6.52
3.76
1.73
93.48
AR 0015 *** SUBSYSTEM SUMMARY REPORT ***
AR 0015 SYSTEM
AR 0015 PROD
AR 0015
DEFINED-CAPACITY
726532.208 MB
DISK-ARRAY-CAP FREE-DISK-ARRAY-CAP
117880.209 MB 57752.311 MB
AR 0015 NET-CAPACITY-LOAD(%) COLL.-FREE-SPACE(%) UNCOLL-FREE-SPACE(%)
AR 0015 TEST PROD OVERALL TEST PROD OVERALL TEST PROD OVERALL
AR 0015 0.00 51.01 51.01
0.00 47.55 47.55 0.00 1.44
1.44
ꢂAR 0015 1I40I READY
ꢃ
Figure 18. Sample Output of IXFP REPORT Command
See B.3, “Report Command” on page 52 for further illustrations.
In the sections that follow we define the field names and column headings of the
reports that IXFP REPORT provides.
4.3.1 Device Detail Report
cuu
This is the device ID of the device to which the data applies.
<---FUNC. CAPACITY (MB)---> This heading covers the fields that provide
information about the functional capacity in megabytes for a certain
device. Functional capacity in this sense is the capacity that would
exist on traditional count key data (CKD) or extended count key data
(ECKD) devices.
DEF
This field contains the functional capacity in megabytes
defined to the subsystem for this specific device.
This field is the functional space allocated by the VTOC.
This data is not currently available for VSE/ESA.
ALLOC
STORED This field contains the functional capacity in megabytes
stored (occupying disk array storage) for the device or
subsystem.
UNUSED This field contains the part of the functional capacity
defined for the device or subsystem that is not mapped
and thus unused (that is, not occupying disk array
storage).
<--- CAPACITY (%)---> This heading covers the fields that provide information
about the percentage of the defined functional capacity assigned to
the individual groups.
ALLOC
This field is the percentage of functional space allocated
by the VTOC. This data is not currently available for
VSE/ESA.
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STORED This field contains the percentage of the defined functional
capacity that contains stored data (occupying disk array
storage) for the device or subsystem.
UNUSED This field contains the percentage of the defined functional
capacity for the device or subsystem that does not yet
contain data and is thus unused (that is, not occupying
disk array storage).
PHYS. USED(MB) This heading covers the field containing the real capacity in
megabytes, that occupies disk array storage, as opposed to the
functional capacity. The difference between the stored and the
physical used capacity is the savings due to compression and
compaction performed by the RVA subsystem for this device.
COMP. RATIO This heading covers the field containing the real compaction ratio,
which is the quotient of functional capacity stored/physical used
capacity.
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4.3.2 Device Summary Report
CAPACITY This column covers the capacity groups that are being differentiated.
<-----TOTAL-----> This column covers the total capacity in megabytes that has
been allocated to the appropriate group in that line. The capacity is
the sum of all the devices that were selected for the report.
<------TOTALS %------> This column shows the percentage of capacity that the
group in the appropriate line is occupying, always compared to the
100% defined functional capacity in the first row. The percentage is
based on all the devices that were selected for the report.
COMP. RATIO This column shows the real compaction ratio, which is the
quotient of the total functional capacity stored/total physical used
capacity and is a measure of the overall compaction for the devices
selected for the report.
4.3.3 Subsystem Summary Report
SYSTEM This column identifies the system to which the capacity outlined in the
appropriate line applies. If a test system has not been configured,
only the PROD system information is provided.
DEFINED-CAPACITY This column contains the functional capacity in megabytes
for the whole subsystem as it has been configured.
DISK-ARRAY-CAP This column contains the total disk array capacity in
megabytes for the whole subsystem that has been installed.
FREE-DISK-ARRAY-CAP This column contains the current free disk array
capacity in megabytes that is still available for allocation by the RVA
subsystem.
NET-CAPACITY-LOAD(%) This column contains the percentage of the disk array
capacity that is currently being occupied by the TEST, PROD, or both
(OVERALL) systems. This is probably the most important value and
has been placed at the beginning of the very last report line to make
it easy to find.
COLL.-FREE-SPACE(%) This column contains the percentage of the array
cylinders in the subsystem that are free array cylinders (that is, the
total space that can be written to).
UNCOLL-FREESPACE(%) This column contains the percentage of the array
capacity originally occupied when a functional track has been
rewritten to a new location in the disk array.
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Chapter 5. Peer-to-Peer Remote Copy
In this chapter we describe the VSE/ESA support for the RVA and the PPRC.
As part of the continuing effort to meet customer requirements for 24-hour 7-day
availability, the RVA Model T82 provides remote copy for disaster and critical
volume protection. PPRC is supported by OS/390, VSE/ESA, and VM/ESA. PPRC
complements the existing availability functions of the RVA, such as the dual
power systems, nonvolatile storage (NVS), and nondisruptive installation and
repair.
PPRC standardizes and streamlines today′s disaster recovery data backup
capabilities by providing data-type independent remote copy. The
implementation provides a choice based on business requirements such as
performance needs, data synchrony criteria, system resource considerations,
operational control requirements, and recovery distance requirements.
PPRC provides an RVA synchronous data copying capability for protection
against loss of access to data in the event of an outage at the primary site.
Updates are sent from the primary RVA directly to the recovery RVA in a cache
to cache communication through dedicated ESCON links between the two RVAs.
The RVA can be located up to 43 km (26.7 mi) from the host. The primary and
secondary volumes must be of the same track geometry.
Figure 19 shows two host systems with an RVA attached to each. The two RVAs
are attached on at least one ESCON path. ESCON Directors can be used to
extend the distance between the two hosts up to 43 km. The second host is
optional if PPRC is being used to migrate data from one RVA to a second within
the same data center.
Figure 19. Peer-to-Peer Remote Copy
Both RVAs can treat writes as DASD fast write (DFW) operations. The primary
RVA write is handled normally, and it is processed as a cache hit whenever
possible; the write to the secondary subsystem is always treated as a write hit.
This capability, and the inherent performance capabilities of the RVA, help to
mitigate the unavoidable performance impacts of writing the data to both RVAs
before signaling the operation as complete to the primary host application.
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Figure 20 on page 34 shows the data flow between the host and the two RVAs.
This would be the sequence of a write operation to the primary RVA:
1. The host application issues a write request to a file, and the VSE/ESA
supervisor converts the request to a start subchannel request to the RVA.
The RVA receives the request, compresses the data as it comes across the
ESCON host adapter, and stores the data in both its cache and NVS.
2. Channel end is returned to the host, indicating that the channel and device
are available for additional I/O operations.
3. At the same time, the updated array data, in its compressed and compacted
form, is transferred across the ESCON channel to the secondary RVA.
Because the primary RVA looks like a host to the secondary, the secondary
RVA stores the data in its cache and NVS and returns channel end to the
primary.
4. When the primary RVA receives the channel end from the secondary, it
presents device end for the write request.
Figure 20. PPRC Data Flow
5.1 PPRC and VSE/ESA Software Requirements
As always, when preparing for new functions, be sure to check with the IBM
Software Support Center before implementing PPRC. Order, install, and test
PTFs, using the customer′s normal change management processes. Check
Information APAR II08303 for the latest list of APARs and PTFs required to use
the PPRC functions.
VSE/ESA Version 2 Release 3.1 is the minimum release level for PPRC support.
APAR fixes DY44407 and DY44616 are needed to support PPRC.
ICKDSF Release 16 ″refreshed″ by APAR PQ20390 contains the support for PPRC
on the RVA.
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5.2 PPRC Hardware Requirements
The hardware requirements for both the primary and secondary RVAs to support
PPRC are:
•
RVA Model T82
•
•
Feature code 7001
PPRC-enabling LIC
(LIC level T04.05.xx is the minimum level)
Remote Service capability
•
Note: We recommend that 4 GB of cache be installed on the RVAs to maximize
performance. We also recommend four ESCON links between the two
subsystems.
5.3 Invoking peer-to-peer remote copy
You initiate PPRC by using the ICKDSF PPRCOPY command with the options
shown in Table 1.
Table 1. ICKDSF PPRCOPY Command Options
PPRCOPY
Command
Option
Function
Primary
Site
Secondary
Site
ESTPATH
Establishes ESCON paths between the RVA of an application
(primary) site and a recovery (secondary) site.
Yes
Yes
No
No
DELPATH
Deletes all established ESCON paths between primary and
secondary site RVA.
ESTPAIR
DELPAIR
Establishes a remote copy device pair.
Yes
Yes
No
No
Removes primary and secondary volumes from PPRC and
returns the devices to a simplex state.
QUERY
Queries the status of a PPRC volume pair and the paths
associated with the RVA for the addressed device.
Yes
No
Yes
Yes
Yes
RECOVER
SUSPEND
Allows the recovery site system to regain control of a DASD
volume on its RVA.
Suspends PPRC operation between a primary and secondary
pair.
Yes
Note: The ICKDSF PPRCOPY commands for the primary device are issued at the primary (application) site.
Commands for the secondary device are issued at the secondary (recovery) site.
Note: The PPRCOPY QUERY VOLUME command should be used to display the
subsystem identifier (SSID), serial number, and channel connection (logical)
address (CCA) of a device. (The CONTROL CONFIGURE (DISPLAY) command
does not work with the RVA. It works only with the 3990/9390 storage controls.)
For an example of using the PPRCOPY command, see 5.5, “Examples of
PPRCOPY Commands” on page 36. For a more detailed description of the
PPRCOPY command, see Device Support Facilities User′s Guide and Reference,
Release 16 Refresh with Peer-to-Peer Remote Copy, GC35-0033.
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5.4 SnapShot Considerations
The RVA provides the unique ability to combine SnapShot functions with PPRC
functions. There are some considerations regarding the interaction of SnapShot
with volumes that are part of a PPRC pair.
You cannot use SnapShot to copy data onto any volume that is part of a PPRC
pair. SnapShot requires that addresses be available on the same RVA
subsystem where the source of the copy resides. If SnapShot is going to be
used on an RVA subsystem that also has PPRC pairs, there must be some
logical volumes on that subsystem that are not part of a PPRC pair. Therefore,
all 256 logical volumes in an RVA subsystem cannot be part of a PPRC pair and
also use SnapShot on that same RVA.
5.4.1 Primary Devices of a PPRC Pair
You cannot use SnapShot to copy to a target that is the primary of a PPRC pair,
regardless of whether the primary is in an active or suspended state. The
primary volume can be the source for a SnapShot copy. Making a copy does not
require modifying the PPRC state of the primary volume.
When dynamically allocating space for a SnapShot target, SnapShot uses all
volumes available to it on a space available basis. It does not check PPRC
status. SnapShot should not be provided a volume list that includes volumes
that are part of a PPRC pair. The SnapShot copy will fail if any part of a data set
is allocated to a volume that is part of a PPRC pair.
5.4.2 Secondary Devices of a PPRC Pair
If SnapShot will be used on a secondary RVA subsystem, there must be space
available on the subsystem in addition to that used by PPRC pairs. You cannot
have all 256 logical volumes as part of PPRC pairs.
Remember that you cannot issue reads or writes to a secondary volume of a
PPRC pair. However, by using a procedure like the following, you can make
SnapShot copies of data from the secondary device—and return it to active
status very quickly:
1. SUSPEND the pair.
2. RECOVER the secondary—returning it to simplex status.
3. Make the SnapShot copy.
4. ESTPAIR RESYNC the secondary to copy only the changes from the primary.
5.5 Examples of PPRCOPY Commands
In this section we demonstrate the use of the ICKDSF PPRCOPY commands to
initiate a PPRC pair.
In the examples that follow, two devices are used. At the primary site, the RVA′s
SSID is x′0057′, the serial number of the storage control is 7390007, and the CCA
is x′D48′. (The serial number actually has two parts—the first two digits indicate
the plant of manufacture, and the last five digits are the machine serial number.)
At the secondary site, the RVA′s SSID is x′053F′, the serial number of the
storage control is 7390014, and the CCA is x′D8C′. (See 5.6, “Physical
Connections to the RVA” on page 38 for the relationship between the logical
control unit number and the CCA.)
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In the examples that follow, the short form of some of the parameters is used.
The long form of these parameters is:
•
NoVeriFY
•
PRIMary
•
SECondary
•
UNITaddress
5.5.1 Setting Up PPRC Paths and Pairs
The sequence of tasks for setting up PPRC at the primary site is:
1. Obtain the SSID, serial number, and CCA for both the primary and secondary
sites′ storage controls. The PPRCOPY QUERY command can be used to
obtain this information. Issue the following commands at the respective host
processors:
PPRCOPY QUERY UNIT(D48)
PPRCOPY QUERY UNIT(D8C)
2. Obtain the physical RVA system adapter IDs (SAIDs). There are 8 for an
8-channel machine and 16 for a 16-channel machine.
3. Use the PPRCOPY QUERY command to check the status of the primary and
secondary devices to determine whether they are in simplex mode and the
paths are already set. Issue the following commands at the respective host
processors:
PPRCOPY QUERY UNIT(D48) PATHS
PPRCOPY QUERY UNIT(D8C) PATHS
4. Establish the path, using ESTPATH:
PPRCOPY ESTPATH UNIT(D48)
PRIM(X′0057′,7390007) SEC(X′053F′,7390014)
LINK(X′004D600′ , X′00510003′)
Warning: The ESTPATH command acts as a replace function. The paths
specified in it establish the link between the storage controls at the primary
and secondary sites. They replace any PPRC paths previously established
between the pair of storage controls.
Note: This example uses two links. Although a single link is possible, it is
advisable to define more than one LINK between the primary and secondary
for availability reasons.
5. Establish a pair, using ESTPAIR:
PPRCOPY ESTPAIR UNIT(D48) MODE(COPY)
PRIM(X′0057′,7390007,X′07′) SEC(X′053F′,7390014,X′0F′ )
Note: The PACE parameter of the ESTPAIR command is ignored.
6. Monitor the progress, using QUERY:
PPRCOPY QUERY UNIT(D48)
5.5.2 Recovering from a Primary Site Failure
Assume that a primary site failure occurred after step 6 above, PPRC has been
activated, and the pair has been established. This example shows the recovery
at the secondary site:
1. Suspend the secondary site device, using SUSPEND:
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PPRCOPY SUSPEND(SEC) UNIT(D48)
PRIM(X′0057′,7390007,X′07′) SEC(X′053F′,7390014,X′0F′ )
2. Check on the secondary device, using QUERY at the recovery site:
PPRCOPY QUERY UNIT(D8C)
3. Issue the RECOVER command at the recovery site:
PPRCOPY RECOVER UNIT(D8C) NVFY
PRIM(X′0057′,7390007,X′07′) SEC(X′053F′,7390014,X′0F′ )
The secondary device is now available for use at the recovery site.
5.5.3 Recovering from a Secondary Site Failure
Assume that a secondary site failure occurred after step 6 of 5.5.1, “Setting Up
PPRC Paths and Pairs” on page 37, PPRC has been activated, and the ESTPAIR
was completed. This example shows the recovery at the primary site:
1. Suspend the primary site device, using SUSPEND:
PPRCOPY SUSPEND(PRIM) UNIT(D48)
PRIM(X′0057′,7390007,X′07′) SEC(X′053F′,7390014,X′0F′ )
2. Repair the problem with the secondary device.
3. Reestablish the PPRC pair. Update the volume by copying only the changed
track(s), using ESTPAIR:
PPRCOPY ESTPAIR UNIT(D48) MODE(RESYNC)
PRIM(X′0057′,7390007,X′07′) SEC(X′053F′,7390014,X′0F′ )
5.5.4 Deleting PPRC Pairs and Paths
Now, assume that you want to terminate the pair—if no failure occurred after
step 6 of 5.5.1, “Setting Up PPRC Paths and Pairs” on page 37. (This example
could be used if you were using PPRC to migrate data from the primary site to
the secondary site.)
1. Issue DELPAIR:
PPRCOPY DELPAIR UNIT(D48)
PRIM(X′0057′,7390007,X′07′) SEC(X′053F′,7390014,X′0F′ )
This command must complete before the paths can be deleted.
2. Issue DELPATH:
PPRCOPY DELPATH UNIT(D48) PRIM(X′0057′,7390007) SEC(X′053F′,7390014)
Note: Execute the PPRCOPY DELPATH command if there are no actively
paired devices between the primary and secondary site RVAs. There is no
single ICKDSF command that can identify all active PPRC devices. For each
device attached to an RVA for which you want to suspend a path, you must
use the PPRCOPY QUERY command.
5.6 Physical Connections to the RVA
Neither the logical control unit (LCU) nor the CCA is intuitively obvious.
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5.6.1 Determining the Logical Control Unit Number for RVA
You can calculate the LCU number by using the CUADD value used in the IOCP
configuration for each LCU. Each of the four CUADDs contains 64 devices.
If the device numbers on the RVA have been generated as a contiguous group of
256 addresses, the LCU can be calculated from the last two digits of the device
number. For example, for devices with an address between A40 and A7F, the
corresponding LCU is LCU1. Table 2 shows the relationship between the device
numbers and LCUs.
5.6.2 Determining the Channel Connection Address
The CCA on an RVA is relative to the LCU and is always between 00 and 3F. If
the device numbers have been generated as a contiguous group of 256
addresses, the CCA can be calculated from the last two digits of the device
number as shown in Table 2. For example, for device numbers AC0 through
AFF, subtract x′C0′ from the last two digits of the device number, and the
corresponding CCAs are 00 through 3F.
Table 2. Determining LCU and CCA Values for the RVA
Device Number
Logical Control
Unit Number
Channel Connection Address
00 - 3F
40 - 7F
80 - BF
C0 - FF
LCU00
LCU01
LCU02
LCU03
00 - 3F
00 - 3F (subtract x′40′ from device number)
00 - 3F (subtract x′80′ from device number)
00 - 3F (subtract x′C0′ from device number)
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Appendix A. RVA Functional Device Configuration
The procedure presented here describes the steps to configure functional
devices through the 9393 operator panel. Figure 21 shows the steps required to
get to the Functional Device Configuration screen.
Figure 21. Functional Device Configuration
On Functional Device Configuration screen CD23 (Figure 22 on page 42) follow
the steps to modify the devices:
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Figure 22. Functional Device Configuration Screen CD23
1. Move the cursor up or down to select the device you want to modify and
press Enter to get to Modify Functional Device screen CD32 (Figure 23).
Figure 23. Modify Functional Device Screen CD32
2. On screen CD32 enter the name of the device, modify the device accordingly,
and press F10 to save and go back to CD23.
3. Repeat steps 1 and 2 for each device you want to modify, or press F3 several
times to leave the screen.
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Appendix B. IXFP Command Examples
In this appendix we present the syntax and use of the various IXFP commands.
B.1 SNAP Command
In this section we present examples of the IXFP SNAP command. The command
syntax is followed by examples of using the command.
Remember: Before you can use the SNAP option, you must bring the target
offline by using the VSE/ESA DVCDN command.
B.1.1 Syntax
Figure 24 shows the syntax of the SNAP command.
┌─,───────────────────────────────────────────────────────────────┐
ꢁ
ꢀꢀ──IXFP────SNAP,─┬──source─┬───────────────────┬─:target─┬────────┬──┬─────────────┬─┴─┬──┬───────────┬────────────ꢀꢂ
│
│
└─(scyl─┬─-scyl─┬─)─┘
└─.ncyl─┘
└─(tcyl)─┘ └─,VOL1=volid─┘ │ └─,NOPROMPT─┘
│
└─source(DSN=′ data-set-name′ ) : target─┬────────┬───────────────────────┘
└─(tcyl)─┘
Figure 24. Syntax of IXFP SNAP Command: Details
SNAP
identifies this command as a SNAP command.
source The device ID=(cuu) or the VOL1 label of the source device
that the user wants to be used as the source when copying
data to a target device. If the source device is identified by its
VOLID, it must be either the only volume with that VOLID or the
only volume with that VOLID that is up (DVCUP). Otherwise an
error message will be issued. The whole volume will be
copied unless the operator has provided additional information
that either identifies a cylinder range or a DSN on the source
device that he or she wants to be copied.
scyl-scyl Specifies the decimal start cylinder and end cylinder
range where copying is to start and to end on the
source device. Cylinder is the smallest entity that can
be specified for any SNAP command function. The
highest (end) cylinder number must not exceed 32767
or the device′s primary number of cylinders and the
start cylinder number must not be higher than the end
cylinder number.
scyl.ncyl Specifies the decimal start cylinder where copying is
to start on the source device and provides the number
of cylinders (ncyl) that should be copied. Cylinder is
the smallest entity that can be specified for any SNAP
command function. The highest resulting cylinder
number must not exceed 32767 or the device′s number
of primary cylinders.
DSN= The data set name identifying the file on the source
device that the operator wants to be copied onto the
target device. The file must be a non-VSAM file. The
file will be copied into the exact extent boundaries
where it was located on the source device. Sequential
Copyright IBM Corp. 1999
43
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access method (SAM) files, however, can be relocated
to a different, single extent disk location on the target
device. In this case, the tcyl operand must be
supplied, but the device must not be a VM partial pack
minidisk. The proper label information (single
FORMAT-1 label) will be created and added to the
target VTOC. Processing multivolume files is the
responsibility of the operator, such that the SNAP
command should be repeated for all the source
volumes containing file extents. The number of
extents to be copied is limited by the limits existing for
the source device. Copying will be performed only if
the appropriate extent boundaries on the target device
are available or have already expired. Otherwise an
error message will be issued. Use the DDSR
command to delete the overlaid file and release the
space.
target
The device ID (cuu) or the VOL1 label of the target device to
which the user wants the data to be copied. You must set the
target device DOWN (DVCDN command) before initiating the
SNAP function, unless the source and target devices are the
same device. If the target device is identified by its VOLID, it
must be either the only volume with that VOLID or the only
volume with that VOLID that is DOWN (DVCDN). Otherwise an
error message is issued. As many extents as allocated on the
source device will be used for file copying to the target device
(DSN=). Otherwise as many cylinders as specified for the
source device, or the entire source volume will be copied to
the target device. Relocation of data records will be assumed
if the specified cylinder range does not match the cylinder
range that was given for the source device. If the cylinder
range does not match the cylinder range of the source device
and the target device is a VM partial-pack minidisk, the
command will be rejected because VM uses virtual cylinder
values for partial-pack minidisks, and the cylinder ranges must
match for VM partial-pack minidisks. The source and the
target devices must be of the same type and must be in the
same RVA subsystem.
tcyl
The decimal specification of where copying is to start
on the target device. Cylinder is the smallest entity
that can be specified for any SNAP command function.
The target cyl specification (tcyl) added to the
specified or calculated ncyl-1 value for the source
device is the resulting target end cylinder address and
must not exceed 32767 or the device′s primary
number of cylinders.
VOL1= Specifies the VOL1 label that the target device is to
receive after the source volume has been copied.
This operand is required if unique VOLIDs are to be
maintained. Otherwise the source and the target
devices would have the same VOL1 label after the
copy function has completed. The VOL1 label
specification for a target device is accepted only when
both the cyl and the DSN= specification have been
omitted, that is, for full volume snaps only.
44 RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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NOPROMPT
Prevents decision-type messages from being issued. Some
messages require an operator reply before the specified
function is initiated. The specification of the NOPROMPT
keyword causes the system to bypass this decision-type
message and initiates the function without any additional
notice.
Note: With the exception of file snapping (DSN=), VSE does not
perform any VTOC checking on the specified target device and thus
does not provide any warning message of any kind, be it overlapping
extents, secured or unexpired files, or anything else. Cylinder or
volume copying will be done unconditionally within the specified or
assumed boundaries.
B.1.2 Using SnapShot to Copy One Volume to Another
In Figure 25 on page 46, we show the copying of one volume to another. We
duplicate the contents of device 80E onto device 80F.
Appendix B. IXFP Command Examples 45
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ꢀixfp report
ꢁ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
AR 0015
DETAIL REPORT ***
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80E 2838.0 N/A
AR 0015 80F 2838.0 N/A
AR 0015
AR 0015 *** DEVICE
AR 0015 CAPACITY
369.2 2468.7 N/A
0.8 2837.1 N/A
13.01 86.99 213.6
0.03 99.97 0.0
1.72
9.65
SUMMARY REPORT
<-----TOTAL-----> <------TOTALS %------>
5676.032 MB 100.00
COMP.
RATIO
AR 0015
AR 0015
AR 0015
AR 0015
AR 0015
DEFINED
STORED
PHYS.USED
UNUSED
370.129 MB
213.688 MB
5305.903 MB
6.52
3.76
1.73
93.48
AR 0015 *** SUBSYSTEM SUMMARY REPORT ***
AR 0015 SYSTEM
AR 0015 PROD
AR 0015
DEFINED-CAPACITY
726532.208 MB
DISK-ARRAY-CAP FREE-DISK-ARRAY-CAP
117880.209 MB 57752.311 MB
AR 0015 NET-CAPACITY-LOAD(%) COLL.-FREE-SPACE(%) UNCOLL-FREE-SPACE(%)
AR 0015 TEST PROD OVERALL TEST PROD OVERALL TEST PROD OVERALL
AR 0015 0.00 51.01 51.01
AR 0015 1I40I READY
0.00 47.55 47.55 0.00 1.44
1.44
ixfp snap,80e:80f,vol1=patev3
AR+0015 IXFP23D SNAP FROM CUU=80E CYL=′0000′ TO CUU=80F CYL=′0000′ NCYL=′0D0B
- REPLY ′ YES′ TO PROCEED
15 yes
AR 0015 IXFP22I SNAP TO CUU= 80F STARTED AT 18:46:51 11/16/1998
AR 0015 IXFP20I SNAP FUNCTION COMPLETED AT 18:46:51 11/16/1998
AR 0015 1I40I READY
ixfp report
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
DETAIL REPORT ***
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015
AR 0015 80E 2838.0 N/A
AR 0015 80F 2838.0 N/A
AR 0015
AR 0015 *** DEVICE
AR 0015 CAPACITY
369.2 2468.7 N/A
369.2 2468.7 N/A
13.01 86.99 213.6
13.01 86.99 213.6
1.72
1.72
SUMMARY REPORT
<-----TOTAL-----> <------TOTALS %------>
5676.032 MB 100.00
COMP.
RATIO
AR 0015
AR 0015
AR 0015
AR 0015
AR 0015
DEFINED
STORED
PHYS.USED
UNUSED
738.558 MB
427.200 MB
4937.474 MB
13.01
7.53
1.72
86.99
AR 0015 *** SUBSYSTEM SUMMARY REPORT ***
AR 0015 SYSTEM
AR 0015 PROD
AR 0015
DEFINED-CAPACITY
726532.208 MB
DISK-ARRAY-CAP FREE-DISK-ARRAY-CAP
117880.209 MB 57752.578 MB
AR 0015 NET-CAPACITY-LOAD(%) COLL.-FREE-SPACE(%) UNCOLL-FREE-SPACE(%)
AR 0015 TEST PROD OVERALL TEST PROD OVERALL TEST PROD OVERALL
AR 0015 0.00 51.01 51.01
0.00 47.67 47.67 0.00 1.32
1.32
ꢂAR 0015 1I40I READY
ꢃ
Figure 25. Console Log from Volume Snap Operation
46 RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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Notes: In Figure 25, in the DEVICE DETAIL REPORT, the data stored for device
80F reflects snapping the data from 80E. Also, the physical used capacity
reflects its source on device 80E. The key indicator is the
NET-CAPACITY-LOAD (%), which shows that the PROD capacity of the
RVA has remained constant at 51.01%.
Using the VOLUME command, we verified that the target volume serial
number had been changed to PATEV3.
The actual time to accomplish the copy was less than 1 sec, as indicated
by messages IXFP22I and IXFP20I, which show the start and end times for
the copy.
We used the above configuration as the base for all other manipulations of the
RVA during the creation of this redbook. The RVA now contains two volumes,
which have the same content but different volume serial numbers.
B.1.3 Using SnapShot to Copy a File from One Volume to Another
In the Figure 26, we show the snapping of a single file from one volume to
another. The example shows the copy being done twice—once without the
NOPROMPT option, and once with it. When NOPROMPT is selected, message
IXFP23D is suppressed.
ꢀixfp snap,80e(dsn=′ test.data.1′): 80f
ꢁ
ꢃ
AR+0015 IXFP23D SNAP FROM CUU=80E DSN=′ TEST.DATA.1′ TO CUU=80F - REPLY ′ YES′
TO PROCEED
15 yes
AR 0015 IXFP22I SNAP TO CUU= 80F STARTED AT 11:44:44 11/20/1998
AR 0015 IXFP20I SNAP FUNCTION COMPLETED AT 11:44:44 11/20/1998
AR 0015 1I40I READY
ixfp snap,80e(dsn=′ test.data.1′): 80f,noprompt
AR 0015 IXFP22I SNAP TO CUU= 80F STARTED AT 18:16:59 11/17/1998
AR 0015 IXFP20I SNAP FUNCTION COMPLETED AT 18:16:59 11/17/1998
ꢂAR 0015 1I40I READY
Figure 26. Making a SnapShot of a Single File
B.1.4 Using SnapShot to Copy Files with Relocation
In the Figure 27 on page 48, we show two attempts to copy a file from device
80E to 80F with relocation of the data on the target volume. The first copy is
successful. The second copy fails because there is already a file on the target
with the same file ID in the VTOC and it is unexpired. (The first would have
failed also except that the first file′s expiration date had been reached.)
Appendix B. IXFP Command Examples 47
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ꢀixfp snap,80e(dsn=′ test.data.1′): 80f(1000),noprompt
ꢁ
ꢃ
AR 0015 IXFP22I SNAP TO CUU= 80F STARTED AT 18:52:48 11/17/1998
AR 0015 IXFP20I SNAP FUNCTION COMPLETED AT 18:52:48 11/17/1998
AR 0015 1I40I READY
ixfp snap,80e(dsn=′ test.data.2′): 80f(2000),noprompt
AR 0015 IXFP25I VTOC ERROR DURING WRITEANY PROCESSING RC=′10′ ON DEVICE=80F
ꢂAR 0015 1I40I READY
Figure 27. Making a SnapShot with Relocation
B.1.5 Other Uses of SnapShot
In this section we present some other uses of SnapShot in a VSE/ESA
environment.
B.1.5.1 Creating a Test Copy of a VSE/ESA System
SnapShot can be used to make a copy of VSE/ESA system-resident volumes for
use in testing new applications in another LPAR. Before taking the snap copy of
DOSRES and SYSWK1, however, you need to be sure that all open files on these
volumes have been closed. An example of this would be the shutting down of
CICS. After DOSRES and SYSWK1 have been snapped, the target volumes could
be reassigned from the production LPAR and reallocated to the test LPAR. You
now have an exact copy of the production system′s DOSRES and SYSWK1.
B.1.5.2 Copying Data from a Production Virtual Machine to a Test
System
IXFP/SnapShot for VSE/ESA can be used to copy selected volumes from the
production virtual machine to the test LPAR, using the procedure in B.1.5.1,
“Creating a Test Copy of a VSE/ESA System.” The difference here is that we
have a functioning VSE/ESA system already running in the test virtual machine
and now want to provide updated data to it.
An example would be that the production virtual machine has access to the full
range of device addresses for the RVA—while the test virtual machine has a
subset of those addresses. The addresses of the test virtual machine would be
in a DVCDN condition to the production virtual machine and thus are available
as a target.
In this case, the production data would be quiesced to ensure that all updates
were completed. SnapShot would be invoked to copy the selected volumes to
addresses accessible by the test virtual machine. The volumes would be made
available again to the production virtual machine.
The test partition would then be able to use a current copy of live data for testing
of new or revised applications.
Notes: The same process could be used for a data warehousing application
where there is no need for up-to-the-minute information, but the full set of
data is required to be in the warehouse.
The same approach could be used where the test virtual machine is
assigned the task of backing up the data as a low priority virtual machine.
48 RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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B.2 DDSR Command
In this section we present examples of the IXFP DDSR command.
Remember: Before you can use the DDSR option against a volume, you must
bring it offline by using the DVCDN VSE/ESA command.
B.2.1 Syntax
ꢀꢀ──IXFP────DDSR─┬────────────────────────────────┬──┬───────────┬──────────────────────────────────────────────────ꢀꢂ
│ ┌────────────────────────────┐ │ └─,NOPROMPT─┘
ꢁ
├──,unit─┬───────────────────┬─┴─┤
│
│
└─(dcyl─┬─-dcyl─┬─)─┘
└─.ncyl─┘
│
│
└─,unit(DSN=′ data-set-name′ ) ─────┘
Figure 28. Syntax of IXFP DDSR Command: Details
DDSR
If specified without any additional operand, the operator can delete the
VTOC entries and all physical space for all non secured files residing on
VSE-managed RVA devices whose associated expiration date has been
reached and which have been created by VSE. A request is sent to the
RVA subsystem, causing the RVA subsystem to release the physical
extents that VSE considers as free space. Once released, these extents
are reclaimed for free space allocation.
If a unit parameter is used, without any additional operands, the data on
the entire volume will be deleted (including the VTOC and the VOL1
label). Therefore the volume must be reinitialized (ICKDSF) before it is
used as a regular data-pack again, assuming it is not going to be used
as a SNAP target device, in which case such an initialization run would
be obsolete. VSE requires the volume to be DOWN (DVCDN command)
if the whole volume or a range of cylinders is to be deleted.
unit
The device ID (cuu) or the VOL1 label of the device that should
be either totally released or, if a data set name (DSN=) or a
cylinder range has been specified, partially released. The
VTOC on this device will remain unchanged unless a file was
released, in which case the appropriate labels will be deleted
from the VTOC. If you release the whole volume, or the
cylinder range containing the VTOC, the VTOC will be deleted.
dcyl-dcyl Specifies the decimal start cylinder and end cylinder
where deletion is to start and to end. Cylinder is the
smallest entity that can be specified for any DDSR
command function. The highest (end) cylinder number
must not exceed 32767, and the start cylinder number
must not be higher than the end cylinder number.
dcyl.ncyl Specifies the decimal start cylinder where deletion is
to start and provides the number of cylinders (ncyl)
that should be released. Cylinder is the smallest
entity that can be specified for any DDSR command
function. The highest resulting cylinder number must
not exceed 32767 or the device′s number of primary
cylinders.
DSN= The data set name identifying the file on the specified
unit that the operator wants to be deleted. The file
must be a non-VSAM file, If the specified unit is in the
Appendix B. IXFP Command Examples 49
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UP (DVCUP) state, the file will be deleted
unconditionally and the space returned to the RVA
freespace. If the device is DOWN (DVCDN), the
command will be rejected and an error message
provided. Processing multivolume files is the
responsibility of the operator, such that the DDSR
command should be repeated for all volumes
containing file extents.
NOPROMPT
Prevents decision-type messages from being issued. Some
messages require an operator reply before the specified
function is initiated. The specification of the NOPROMPT
keyword causes the system to bypass this decision-type
message and initiates the function without any additional
notice.
B.2.2 Using DDSR to Delete a Single Data Set
To show the effects of using DDSR on the RVA, we deleted a single data set from
the RVA, using the commands in Figure 29.
ꢀixfp report,80f
ꢁ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
DETAIL REPORT ***
AR 0015
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80F 2838.0 N/A
AR 0015 1I40I READY
ixfp ddsr,patev3(dsn=′ test.data.3′ )
AR+0015 IXFP29D DDSR FOR CUU=80F DSN=′ TEST.DATA.3 - REPLY ′ YES′ FOR DELETION
369.2 2468.7 N/A
13.01 86.99 213.6
1.72
15 yes
AR 0015 1I40I READY
ixfp report,80f
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
DETAIL REPORT ***
AR 0015 <---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80F 2838.0 N/A
288.9 2549.0 N/A
10.18 89.82 210.6
1.37
ꢂAR 0015 1I40I READY
ꢃ
Figure 29. Console Log from Releasing the Space of One Data Set on a Volume
B.2.3 Using DDSR to Delete the Contents of a Volume
In Figure 30 on page 51, we used the DDSR option to free the entire volume with
serial number PATEV3. After the space was released, all the data and the
volume serial number were erased from the volume. The volume must be
reinitialized to put the volume label back on the device.
50 RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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ꢀixfp report,80f
ꢁ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
DETAIL REPORT ***
AR 0015
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80F 2838.0 N/A
AR 0015 1I40I READY
ixfp ddsr,patev3
AR+0015 IXFP29D DDSR FOR CUU=80F (WHOLE VOLUME) - REPLY ′ YES′ FOR DELETION
15 yes
369.2 2468.7 N/A
13.01 86.99 213.6
1.72
AR 0015 1I40I READY
ixfp report,80f
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
DETAIL REPORT ***
AR 0015 <---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80F 2838.0 N/A
0.0 2838.0 N/A
0.00 100.00
0.0 N/A
ꢂAR 0015 1I40I READY
ꢃ
Figure 30. Console Log from Releasing the Space of an Entire Volume
Note: When you use DDSR, IXFP/SnapShot for VSE/ESA always prompts the
operator before executing the desired function, unless the NOPROMPT keyword
is selected—in which case, the function will execute without an operator prompt.
B.2.4 Using DDSR to Delete the Free Space on an RVA
Figure 31 on page 52 shows the result of using DDSR to release the space
occupied by expired files in a subsystem. Both the space occupied by the data
and the VTOC entry are released. (There are two occurrences of TEST.DATA.1
because device 80E was snapped to 80F.) Note that the capacity stored
decreases while the capacity unused increases.
Appendix B. IXFP Command Examples 51
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ꢀixfp report,80e,80f
ꢁ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
DETAIL REPORT ***
AR 0015
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80E 2838.0 N/A
AR 0015 80F 2838.0 N/A
AR 0015 1I40I READY
ixfp ddsr
369.2 2468.7 N/A
369.2 2468.7 N/A
13.01 86.99 213.6
13.01 86.99 213.6
1.72
1.72
AR+0015 IXFP26D ′ TEST.DATA.1′ HAS EXPIRED ON CUU=80E - REPLY ′ YES′ FOR
DELETION
15 yes
AR+0015 IXFP26D ′ TEST.DATA.1′ HAS EXPIRED ON CUU=80F - REPLY ′ YES′ FOR
DELETION
15 yes
AR 0015 1I40I READY
ixfp report,80e,80f
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
AR 0015 <---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
DETAIL REPORT ***
AR 0015 80E 2838.0 N/A
AR 0015 80F 2838.0 N/A
345.6 2492.3 N/A
345.6 2492.3 N/A
12.18 87.82 212.7
12.18 87.82 212.7
1.62
1.62
ꢂAR 0015 1I40I READY
ꢃ
Figure 31. Console Log from Releasing the Space of All Expired Files in the RVA
B.3 Report Command
In this section we present examples of using the IXFP REPORT command.
B.3.1 Syntax
┌───────┐
ꢁ
ꢀꢀ──IXFP────REPORT──┬─────┬┴────────────────────────────────────────────────────────────────────────────────────────ꢀꢂ
└─,id─┘
Figure 32. Syntax of IXFP REPORT Command: Details
REPORT Provides information about the utilization of the RVA devices or, if the
id parameter has been omitted, of the whole subsystem including all
devices known (ADDed) to the VSE system.
id
The id of the device or the scope of devices for which detailed
device utilization information is requested.
The id can be either a VOL1 label, a channel ID, a
channel+CU ID, or the device ID.
″IXFP REPORT,80″ will thus provide report information for all
capable devices (non-partial-pack minidisks) in the device ID
range X′800′ through X′80F′ that have been ADDed to the
VSE/ESA system during IPL.
If we had specified the address for a non-RVA device, a report
would not be produced. If the RVA had 256 devices specified
52 RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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and they were all on channel 8, ″IXFP REPORT,8″ would show
all the devices in the RVA, because a storage control address
was not specified.
Note: The REPORT function, if used under VM, only works for full-pack
minidisks or dedicated devices.
B.3.2 Reporting on the Capacity of a Single Volume
Figure 33 shows the response to a single volume request.
ꢀixfp report,80e
ꢁ
ꢃ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
DETAIL REPORT ***
AR 0015
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80E 2838.0 N/A
392.9 2445.1 N/A
13.84 86.16 214.4
1.83
ꢂAR 0015 1I40I READY
Figure 33. Single Volume IXFP REPORT
B.3.3 Reporting on the Capacity of Multiple Volumes
Figure 34 shows the response to a multiple volume request.
ꢀixfp report,80e,80f
ꢁ
ꢃ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
DETAIL REPORT ***
AR 0015
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80E 2838.0 N/A
AR 0015 80F 2838.0 N/A
ꢂAR 0015 1I40I READY
392.9 2445.1 N/A
392.9 2445.1 N/A
13.84 86.16 214.4
13.84 86.16 214.4
1.83
1.83
Figure 34. Multiple Volume IXFP REPORT
B.3.4 Reporting on the Capacity of the RVA Subsystem
Figure 35 on page 54 shows the response to an entire subsystem request.
Appendix B. IXFP Command Examples 53
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ꢀixfp report
ꢁ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
AR 0015
DETAIL REPORT ***
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80E 2838.0 N/A
AR 0015 80F 2838.0 N/A
AR 0015
AR 0015 *** DEVICE
AR 0015 CAPACITY
392.9 2445.1 N/A
392.9 2445.1 N/A
13.84 86.16 214.4
13.84 86.16 214.4
1.83
1.83
SUMMARY REPORT
<-----TOTAL-----> <------TOTALS %------>
5676.032 MB 100.00
COMP.
RATIO
AR 0015
AR 0015
AR 0015
AR 0015
AR 0015
DEFINED
STORED
PHYS.USED
UNUSED
785.816 MB
428.908 MB
4890.216 MB
13.84
7.56
1.83
86.16
AR 0015 *** SUBSYSTEM SUMMARY REPORT ***
AR 0015 SYSTEM
AR 0015 PROD
AR 0015
DEFINED-CAPACITY
726532.208 MB
DISK-ARRAY-CAP FREE-DISK-ARRAY-CAP
117880.209 MB 57750.030 MB
AR 0015 NET-CAPACITY-LOAD(%) COLL.-FREE-SPACE(%) UNCOLL-FREE-SPACE(%)
AR 0015 TEST PROD OVERALL TEST PROD OVERALL TEST PROD OVERALL
AR 0015 0.00 51.01 51.01
0.00 47.55 47.55 0.00 1.44
1.44
ꢂAR 0015 1I40I READY
ꢃ
Figure 35. Entire Subsystem IXFP REPORT
Submitting the batch job shown in Figure 36 would achieve the same results.
// JOB WCWTEST1
// LOG
// EXEC DTRIATTN,PARM=′ IXFP REPORT′
/&
Figure 36. JCL to Produce an Entire Subsystem IXFP REPORT
B.4 IXFP/SnapShot Setup Job Streams
For the verification of IXFP/SnapShot for VSE/ESA, two RVA disks were made
available. In this section we present the job streams used to allocate and create
the test data. We used the following job stream to release the space on the RVA
and write the VTOCs to the disks:
// JOB INITDISK
DVCDN X′80E′
// EXEC DTRIATTN,PARM=′ IXFP DDSR,80E′
DVCDN X′80F′
// EXEC DTRIATTN,PARM=′ IXFP DDSR,80F′
// LOG
* WAIT UNTIL IXFP/SNAPSHOT HAS RELEASED THE SPACE BEFORE CONTINUING
// EXEC IESWAIT
DVCUP X′80E′
DVCUP X′80F′
// ASSGN SYS004,80E,SHR
// EXEC ICKDSF,SIZE=AUTO
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INIT SYSNAME(SYS004) NOVERIFY PURGE VOLID(PATEV1)
/*
// ASSGN SYS004,80F,SHR
// EXEC ICKDSF,SIZE=AUTO
INIT SYSNAME(SYS004) NOVERIFY PURGE VOLID(PATEV2)
/*
/&
Figure 37 shows the console log from the above job stream. Notice that we
used DDSR to free any extraneous space on the disks.
ꢀBG 0000 // JOB INITDISK
ꢁ
DATE 11/16/1998, CLOCK 14/39/38
BG 0000 1A86I FOLLOWING ASSIGNMENTS ARE RELEASED
BG 0000
IXFP DDSR,80E
** NONE **
AR+0015 IXFP29D DDSR FOR CUU=80E (WHOLE VOLUME) - REPLY ′ YES′ FOR DELETION
BG 0000 1A86I FOLLOWING ASSIGNMENTS ARE RELEASED
BG 0000
15 yes
** NONE **
AR 0015 1I40I READY
IXFP DDSR,80F
AR+0015 IXFP29D DDSR FOR CUU=80F (WHOLE VOLUME) - REPLY ′ YES′ FOR DELETION
BG 0000 * WAIT UNTIL IXFP/SNAPSHOT HAS RELEASED THE SPACE BEFORE CONTINUING
15 yes
AR 0015 1I40I READY
BG 0000 DVCUP X′80E′
BG 0000 DVCUP X′80F′
BG 0000 EOJ INITDISK MAX.RETURN CODE=0000
DATE 11/16/1998, CLOCK 14/40/03, DURATION 00/00/24
ꢂ
ꢃ
Figure 37. Console Log from Formatting RVA to Receive Test Data
Figure 38 on page 56 shows the report of the setup job. Notice that there is no
data stored on either of the volumes.
Appendix B. IXFP Command Examples 55
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ꢀixfp report
ꢁ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
AR 0015
DETAIL REPORT ***
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80E 2838.0 N/A
AR 0015 80F 2838.0 N/A
AR 0015
AR 0015 *** DEVICE
AR 0015 CAPACITY
0.0 2838.0 N/A
0.0 2838.0 N/A
0.00 100.00
0.00 100.00
0.0 N/A
0.0 N/A
SUMMARY REPORT
<-----TOTAL-----> <------TOTALS %------>
5676.032 MB 100.00
COMP.
RATIO
AR 0015
AR 0015
AR 0015
AR 0015
AR 0015
DEFINED
STORED
PHYS.USED
UNUSED
0.000 MB
0.000 MB
5676.032 MB
0.00
0.00
0.00
100.00
AR 0015 *** SUBSYSTEM SUMMARY REPORT ***
AR 0015 SYSTEM
AR 0015 PROD
AR 0015
DEFINED-CAPACITY
726532.208 MB
DISK-ARRAY-CAP FREE-DISK-ARRAY-CAP
117880.209 MB 57966.680 MB
AR 0015 NET-CAPACITY-LOAD(%) COLL.-FREE-SPACE(%) UNCOLL-FREE-SPACE(%)
AR 0015 TEST PROD OVERALL TEST PROD OVERALL TEST PROD OVERALL
AR 0015 0.00 50.83 50.83
0.00 47.86 47.86 0.00 1.31
1.31
ꢂAR 0015 1I40I READY
ꢃ
Figure 38. RVA Status before Loading Any Data
We used the following job stream (which uses DITTO to create six files) to load
the data onto the RVA:
// JOB BUILD DATA ON PATEV1 (80E)
// OPTION NODUMP
// ASSGN SYS005,DISK,VOL=PATEV1,SHR
// DLBL OUTPUT,′ EXPIRED.DSF.DATA.FILE′,1998/300,SD,DSF
// EXTENT SYS005,PATEV1,1,1,4035,1500
// UPSI 1
// LOG
* DISPLAY RVA DATA FOR PATEV1 (80E) -- BEFORE DATA LOAD.
// NOLOG
// EXEC DTRIATTN,PARM=′ IXFP REPORT,PATEV1′
// LOG
* BUILD EXPIRED, DATA-SECURED FILE ON 80E
*
17,000 RECORDS, 4,000 BYTES LONG, RANDOM FILL CHARACTER
// NOLOG
// EXEC DITTO,SIZE=AUTO
$$DITTO BSQ FILEOUT=OUTPUT,RECSIZE=4000,NLRECS=17000,FILLCHAR=RAND,
$$DITTO
$$DITTO EOJ
/*
X
BLKFACTOR=1
// DLBL OUTPUT,′ UNEXPRED.DSF.DATA.FILE′,1998/365,SD,DSF
// EXTENT SYS005,PATEV1,1,1,5535,1500
// LOG
* BUILD UNEXPIRED, DATA-SECURED FILE ON 80E
*
17,000 RECORDS, 4,000 BYTES LONG, RANDOM FILL CHARACTER
// NOLOG
// EXEC DITTO,SIZE=AUTO
$$DITTO BSQ FILEOUT=OUTPUT,RECSIZE=4000,NLRECS=17000,FILLCHAR=RAND,
$$DITTO
$$DITTO EOJ
X
BLKFACTOR=1
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/*
// DLBL OUTPUT,′ TEST.DATA.1′,1998/300,SD
// EXTENT SYS005,PATEV1,1,1,135,450
// LOG
* BUILD EXPIRED SEQUENTIAL FILE ON 80E
*
5,000 RECORDS, 4,000 BYTES LONG, ″1″ FILL CHARACTER
// NOLOG
// EXEC DITTO,SIZE=AUTO
$$DITTO BSQ FILEOUT=OUTPUT,RECSIZE=4000,NLRECS=5000,FILLCHAR=1,
$$DITTO
$$DITTO EOJ
/*
X
X
X
X
BLKFACTOR=1
// DLBL OUTPUT,′ TEST.DATA.2′ , , SD
// EXTENT SYS005,PATEV1,1,1,585,450
// LOG
* BUILD SEQUENTIAL FILE ON 80E
*
5,000 RECORDS, 4,000 BYTES LONG, ″2″ FILL CHARACTER
// NOLOG
// EXEC DITTO,SIZE=AUTO
$$DITTO BSQ FILEOUT=OUTPUT,RECSIZE=4000,NLRECS=5000,FILLCHAR=2,
$$DITTO
$$DITTO EOJ
/*
BLKFACTOR=1
// DLBL OUTPUT,′ TEST.DATA.3′ , , SD
// EXTENT SYS005,PATEV1,1,1,1035,1500
// LOG
* BUILD SEQUENTIAL FILE ON 80E
*
17,000 RECORDS, 4,000 BYTES LONG, ″3″ FILL CHARACTER
// NOLOG
// EXEC DITTO,SIZE=AUTO
$$DITTO BSQ FILEOUT=OUTPUT,RECSIZE=4000,NLRECS=17000,FILLCHAR=3,
$$DITTO
$$DITTO EOJ
/*
BLKFACTOR=1
* BUILD SEQUENTIAL FILE ON 80E
*
5,000 RECORDS, 4,000 BYTES LONG, ″1″ FILL
// LOG
* BUILD SEQUENTIAL FILE ON 80E
*
17,000 RECORDS, 4,000 BYTES LONG, RANDOM FILL CHARACTER
// NOLOG
// EXEC DITTO,SIZE=AUTO
$$DITTO BSQ FILEOUT=OUTPUT,RECSIZE=4000,NLRECS=17000,FILLCHAR=RAND,
$$DITTO
$$DITTO EOJ
/*
BLKFACTOR=1
// LOG
* DISPLAY RVA DATA FOR PATEV1 (80E) -- AFTER DATA LOAD.
// NOLOG
// EXEC DTRIATTN,PARM=′ IXFP REPORT,PATEV1′
// EXEC IESWAIT
// EXEC LISTLOG
/&
The result (Figure 39 on page 58) is six sequential files with varying types of
data. Two of the files are data secured to prevent ″unauthorized″ access. Three
of the files are highly compressible because they contain a repeating data
character, and the other three have random fill characters.
Appendix B. IXFP Command Examples 57
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ꢀixfp report
ꢁ
AR 0015 SUBSYSTEM 1321117
AR 0015 *** DEVICE
AR 0015
DETAIL REPORT ***
<---FUNC. CAPACITY (MB)---> <---CAPACITY (%)---> PHYS. COMP.
AR 0015 CUU DEF ALLOC STORED UNUSED ALLOC STORED UNUSED USED(MB) RATIO
AR 0015 80E 2838.0 N/A
AR 0015 80F 2838.0 N/A
AR 0015
AR 0015 *** DEVICE
AR 0015 CAPACITY
369.2 2468.7 N/A
0.8 2837.1 N/A
13.01 86.99 213.6
0.03 99.97 0.0
1.72
9.65
SUMMARY REPORT
<-----TOTAL-----> <------TOTALS %------>
5676.032 MB 100.00
COMP.
RATIO
AR 0015
AR 0015
AR 0015
AR 0015
AR 0015
DEFINED
STORED
PHYS.USED
UNUSED
370.129 MB
213.688 MB
5305.903 MB
6.52
3.76
1.73
93.48
AR 0015 *** SUBSYSTEM SUMMARY REPORT ***
AR 0015 SYSTEM
AR 0015 PROD
AR 0015
DEFINED-CAPACITY
726532.208 MB
DISK-ARRAY-CAP FREE-DISK-ARRAY-CAP
117880.209 MB 57754.953 MB
AR 0015 NET-CAPACITY-LOAD(%) COLL.-FREE-SPACE(%) UNCOLL-FREE-SPACE(%)
AR 0015 TEST PROD OVERALL TEST PROD OVERALL TEST PROD OVERALL
AR 0015 0.00 51.01 51.01
0.00 47.67 47.67 0.00 1.32
1.32
ꢂAR 0015 1I40I READY
ꢃ
Figure 39. RVA Status after Loading Data
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Appendix C. VSE/VSAM Considerations
VSE/VSAM support is not included in IXFP/SnapShot for VSE/ESA. This does not
mean however that you cannot take advantage of IXFP/SnapShot for VSE/ESA
with VSE/VSAM data sets.
It does mean that there is no support in IXFP/SnapShot for VSE/ESA to
dynamically adjust the VSAM catalog to reflect the target of the SnapShot copy.
However, through job control, a user catalog can point to the SnapShot copy and
access the data on the copy. In our test, we created a VSAM user catalog
(UCAT), space, and cluster on a volume at address 80E with serial number
PATEV1. We then snapped the volume to device address 80F with serial number
PATEV2, changing the volume serial number to PATEV1 in the process using the
following procedure:
1. Close any opened files on the volume. (This may include shutting down
CICS or other applications.)
2. Issue the following commands:
0 dvcdn 80f
ixfp snap,patev1:80f,vol1=patev1
0 dvcup 80f
3. The JCL to access the source volume is:
// DLBL UCAT01,′VOLSER.USER.CATALOG′,,VSAM
// DLBL DDNAME,′USER.FILE.ID′,,VSAM,CAT=UCAT01
4. To process data from the target volume, use the following JCL to access the
VSAM file:
// DLBL UCAT01,′VOLSER.USER.CATALOG′,,VSAM
// EXTENT SYS099,PATEV1
// ASSGN SYS099,80F,SHR
// DLBL DDNAME,′USER.FILE.ID′,,VSAM,CAT=UCAT01
// EXTENT SYS099,PATEV1
The first JCL finds the source volume because its device address is lower
than the target volume′s. The second JCL can only use the data from device
address 80F because we have explicitly pointed to that device with the
ASSGN statement. In this case, we can access the snapped copy of the
VSAM files on device 80F and copy it to the original volume, if required as
part of a recovery effort.
5. After using the target volume and its VSAM file, release the space back to
the RVA by issuing the ixfp ddsr 80f command. (Remember that 80F would
have to be DVCDNed before the IXFP DDSR command could be successfully
executed.) You can also retain it online for use in a VSE/ESA partition—as
long as the duplicate volume serial number and UCAT will not create a
problem.
Copyright IBM Corp. 1999
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Warning
This approach may not work with VSAM files that specify share options 2 or
4. The reason for the problem here is that, with SHROPTN(2), or
SHROPTN(4), VSE/VSAM′s method of enqueuing the file (to protect it during a
write) uses the file ID of the VSAM catalog and the volume serial number of
the volume.
Notes:
Share option 2 provides that the file may be opened by more than one
request for input processing and, at the same time, by one request for
output processing. This option ensures write integrity; however, the
file might be modified while records are retrieved from it, so every
user must ensure his or her own file′s read integrity.
Share option 4 provides that a key-sequenced or relative-record file
can be opened by any number of requests (ACBs) for both input and
output processing by users in the first system requesting output to the
file. Once a file has been opened for output by one system,
VSE/VSAM accepts only open for input requests from another system.
Share option 4 for an entry-sequenced file is treated as though it were
a share option 2.
If, for any reason, the file were to be opened for output processing
while the target is online to the VSE/ESA system, return code x′A8′
(168) might be returned indicating that the data set is in use. This is
caused by the lock with duplicate volume serial numbers. The
situation can be corrected by canceling and restarting the job after
taking the target offline; there is no data integrity exposure.
C.1 Backing up VSAM Volumes
There are several instances where SnapShot can be used to back up VSAM
volumes for use within the same LPAR or different LPARs. In a first example,
we wanted to copy a VSAM volume that contained both the user catalog (UCAT)
and all of the UCAT′s files on a single volume. In this case, we would make a
snap copy of the volume with the target volume having a volume serial number
different from that of the source. Before we actually issue the IXFP SNAP
command, any files that are open have to be closed so that the data is written to
the disk. Then a utility like VSE/FASTCOPY or the VM/ESA DDR could be used
to back up the volume to tape. If all that we were trying to establish was a
restart copy in case there was an application failure, the tape backup is
superfluous. The VSAM volume cannot be used because the VSAM catalog′s
contents include the volume serial number of the volume on which it was
created. If VSAM finds a different volume serial number, it cannot process the
catalog.
In a second example, the VSAM files reside on several volumes and have a
unique UCAT for these files. Here, we would use the same procedure as above
to quiesce activity against the files. The volumes containing the files would then
be snap copied and, optionally, backed up to tape.
In a third example, we again have one or more VSAM volumes controlled by a
single UCAT. This time, we would like to carry the data from our production
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LPAR to a test LPAR. We would quiesce the files as above. And we would also
make the SnapShot copy. But, this time, the volume serial number of the source
would be retained on the target. Because the target volume for a SNAP copy is
always in a DVCDN condition, the duplicate volume serial number would not
interfere with the production system. The target volumes would then be taken
away from the VSE production system through the use of the offline command.
The volumes would then be placed online to the test LPAR and then, using the
IDCAMS IMPORT CONNECT to access the UCAT, you can use the files in the test
LPAR. In this case, IDCAMS BACKUP could be used to back up the files.
Appendix C. VSE/VSAM Considerations 61
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Appendix D. IOCDS Example
IOCDS must have an LCU defined for each group of 64 functional devices. Each
LCU should have two CNTLUNIT macros, one for each cluster.
Figure 40 shows a sample IOCDS from the RVA.
CHPID
PATH=((0A),(0B),(0C),(0D)),TYPE=CNC
CNTLUNIT CUNUMBR=001,
UNIT=3990,
UNITADD=((00,64)),
PATH=(0A,0B),
CUADD=2
CNTLUNIT CUNUMBR=002,
UNIT=3990,
UNITADD=((00,64)),
PATH=(0C,0D),
CUADD=2
CNTLUNIT CUNUMBR=003,
UNIT=3990,
UNITADD=((00,64)),
PATH=(0A,0B),
CUADD=3
CNTLUNIT CUNUMBR=004,
UNIT=3990,
UNITADD=((00,64)),
PATH=(0C,0D),
CUADD=3
IODEVICE UNIT=3390,
ADDRESS=(180,64),
UNITADD=00,
STADET=Y,
CUNUMBR=(001,002),
IODEVICE UNIT=3390,
ADDRESS=(1C0,64),
UNITADD=00,
STADET=Y,
CUNUMBR=(003,004),
Figure 40. IOCDS Example
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Appendix E. Special Notices
This publication is intended to help IBM, Business Partner, and customer
personnel understand how VSE/ESA provides support for the RAMAC Virtual
Array. The information in this publication is not intended as the specification of
any programming interfaces that are provided by IXFP/SnapShot for VSE/ESA,
RAMAC Virtual Array, and peer-to-peer remote copy. See the PUBLICATIONS
section of the IBM Programming Announcement for IXFP/SnapShot for VSE/ESA
and peer-to-peer remote copy for the RAMAC Virtual Array for more information
about what publications are considered to be product documentation.
References in this publication to IBM products, programs or services do not
imply that IBM intends to make these available in all countries in which IBM
operates. Any reference to an IBM product, program, or service is not intended
to state or imply that only IBM′s product, program, or service may be used. Any
functionally equivalent program that does not infringe any of IBM′s intellectual
property rights may be used instead of the IBM product, program or service.
Information in this book was developed in conjunction with use of the equipment
specified, and is limited in application to those specific hardware and software
products and levels.
IBM may have patents or pending patent applications covering subject matter in
this document. The furnishing of this document does not give you any license to
these patents. You can send license inquiries, in writing, to the IBM Director of
Licensing, IBM Corporation, North Castle Drive, Armonk, NY 10504-1785.
Licensees of this program who wish to have information about it for the purpose
of enabling: (i) the exchange of information between independently created
programs and other programs (including this one) and (ii) the mutual use of the
information which has been exchanged, should contact IBM Corporation, Dept.
600A, Mail Drop 1329, Somers, NY 10589 USA.
Such information may be available, subject to appropriate terms and conditions,
including in some cases, payment of a fee.
The information contained in this document has not been submitted to any
formal IBM test and is distributed AS IS. The information about non-IBM
(″vendor″) products in this manual has been supplied by the vendor and IBM
assumes no responsibility for its accuracy or completeness. The use of this
information or the implementation of any of these techniques is a customer
responsibility and depends on the customer′s ability to evaluate and integrate
them into the customer′s operational environment. While each item may have
been reviewed by IBM for accuracy in a specific situation, there is no guarantee
that the same or similar results will be obtained elsewhere. Customers
attempting to adapt these techniques to their own environments do so at their
own risk.
Any pointers in this publication to external Web sites are provided for
convenience only and do not in any manner serve as an endorsement of these
Web sites.
Any performance data contained in this document was determined in a
controlled environment, and therefore, the results that may be obtained in other
Copyright IBM Corp. 1999
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operating environments may vary significantly. Users of this document should
verify the applicable data for their specific environment.
Reference to PTF numbers that have not been released through the normal
distribution process does not imply general availability. The purpose of
including these reference numbers is to alert IBM customers to specific
information relative to the implementation of the PTF when it becomes available
to each customer according to the normal IBM PTF distribution process.
The following terms are trademarks of the International Business Machines
Corporation in the United States and/or other countries:
CICS
ECKD
IBM
RAMAC
VSE/ESA
DFSORT
ESCON
OS/390
VM/ESA
The following terms are trademarks of other companies:
IXFP
Storage Technology Corporation
Iceberg
StorageTek
Storage Technology Corporation
Storage Technology Corporation
C-bus is a trademark of Corollary, Inc.
Java and HotJava are trademarks of Sun Microsystems, Incorporated.
Microsoft, Windows, Windows NT, and the Windows 95 logo are trademarks
or registered trademarks of Microsoft Corporation.
PC Direct is a trademark of Ziff Communications Company and is used
by IBM Corporation under license.
Pentium, MMX, ProShare, LANDesk, and ActionMedia are trademarks or
registered trademarks of Intel Corporation in the U.S. and other
countries.
UNIX is a registered trademark in the United States and other
countries licensed exclusively through X/Open Company Limited.
Other company, product, and service names may be trademarks or
service marks of others.
66 RAMAC Virtual Array, Peer-to Peer Remote VSE/ESA
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Appendix F. Related Publications
The publications listed in this section are considered particularly suitable for a
more detailed discussion of the topics covered in this redbook.
F.1 International Technical Support Organization Publications
For information on ordering these ITSO publications see “How to Get ITSO
Redbooks” on page 69.
•
IBM RAMAC Virtual Array, SG24-4951
•
RAMAC Virtual Array: Implementing Peer-to-Peer Remote Copy, SG24-5338
•
Implementing SnapShot, SG24-2241
F.2 Redbooks on CD-ROMs
Redbooks are also available on CD-ROMs. Order a subscription and receive
updates 2-4 times a year.
CD-ROM Title
Subscription
Number
Collection Kit
Number
System/390 Redbooks Collection
SBOF-7201
SBOF-7370
SBOF-7240
SBOF-6899
SBOF-6898
SBOF-7270
SBOF-7230
SBOF-7205
SBOF-8700
SBOF-7290
SK2T-2177
SK2T-6022
SK2T-8038
SK2T-8039
SK2T-8044
SK2T-2849
SK2T-8040
SK2T-8041
SK2T-8043
SK2T-8037
Networking and Systems Management Redbooks Collection
Transaction Processing and Data Management Redbook
Lotus Redbooks Collection
Tivoli Redbooks Collection
AS/400 Redbooks Collection
RS/6000 Redbooks Collection (HTML, BkMgr)
RS/6000 Redbooks Collection (PostScript)
RS/6000 Redbooks Collection (PDF Format)
Application Development Redbooks Collection
F.3 Other Publications
These publications are also relevant as further information sources:
•
Device Support Facilities User′s Guide and Reference, Release 16 Refresh
with Peer-to-Peer Remote Copy, GC35-0033
•
•
IOCP User′s Guide and ESCON Channel-to-Channel Reference, GC38-0401
Memo to Licensees (ships with the IXFP/SnapShot for VSE/ESA feature)
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How to Get ITSO Redbooks
This section explains how both customers and IBM employees can find out about ITSO redbooks, redpieces, and
CD-ROMs. A form for ordering books and CD-ROMs by fax or e-mail is also provided.
•
Redbooks Web Site http://www.redbooks.ibm.com/
Search for, view, download or order hardcopy/CD-ROMs redbooks from the redbooks Web site. Also read
redpieces and download additional materials (code samples or diskette/CD-ROM images) from this redbooks
site.
Redpieces are redbooks in progress; not all redbooks become redpieces and sometimes just a few chapters
will be published this way. The intent is to get the information out much quicker than the formal publishing
process allows.
•
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Index
functional device table
See FDT
functional track directory
See FTD
functional track table
See FTT
B
batch
application processing 10
data set reorganization
incremental backup
interim backup 10
report generation 10
9
9
H
hardware
C
availability 10
requirements 13
catalog
implications
CKD
4
1
compaction
compression
configuration
device 41
count key data
See CKD
2
I
2
I/O configuration definition data set
See IOCDS
I/O Configuration Program
See IOCP
IBM Extended Facilities Program
See IXFP
ICKDSF
D
commands 15
initialization 15
IOCDS
data placement
DDSR
8
command detail 49
command syntax 25
cylinder range 26
example 50
example 63
IOCP
definition 14
IXFP
expired files 25
file 27
volume 26
function
1
IXFP/SnapShot for VSE/ESA
command environment 17
command syntax 20
functions 17
deleted data space release
See DDSR
device definition 41
device emulation 14
dynamic configuration 10
L
LIC requirements 13
E
ESCON connectivity 14
N
NCL
description
net capacity load
See NCL
1
F
FBA
FDT
1
1
fixed block architecture
See FBA
P
freespace collection
1
peer-to-peer remote copy
See PPRC
FTD
FTT
1
2
physical copy
PPRC
3
functional device
description
functional device definition 41
5
1
addressing 38
benefits 33
command syntax 36
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PPRC (continued)
V
distance 33
hardware requirements 34
operation 33
PPRCOPY command 35
recovery 37
virtual disk architecture
VM minidisks 17
VSE/VSAM
1
sample JCL 59
SnapShot 22, 59
volume backup 60
SnapShot considerations 36
software requirements 34
PPRCOPY command
parameters 35
R
REPORT
command detail 52
command syntax 27
device detail 29
device summary 31
example 53
sample output 54
requirements
PPRC 34
S
SnapShot
architecture
3
command details 43
command syntax 21
cylinder range 23
example 45
file relocation 47
file snap 24
logical copy
operation
3
4
PPRC considerations 36
resources
3
test system 48
volume snap 21
VSE/VSAM 22, 59
software
requirements 13
space management
storage management
system testing
7
7
SnapShot 48
T
TNT
description
2
reference counter 2, 4
track number table
See TNT
U
update in place
1
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RAMAC Virtual Array, Peer-to-Peer Remote Copy,
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RAMAC Virtual Array, Peer-to-Peer Remote Copy,
and IXFP/SnapShot for VSE/ESA
SG24-5360-00
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