Wednesday, September 25, 2024

Migrating to Db2 13 for z/OS: What About Non-Universal Table Spaces?

I recently communicated with a Db2 for z/OS system administrator who had some concerns about non-universal table spaces in the context of his organization's planned migration from Db2 12 to Db2 13. This person asked important questions about the presence of non-universal table spaces in his Db2 environment and how those database objects might affect his team's plans for Db2 12-to-13 migration. Looking over that communications thread, I found myself thinking (as I often have over the years) that it could be the basis for a blog entry that would be helpful for people in the wider Db2 for z/OS user community; so, here we go.


Terminology: universal and non-universal table spaces

Logically speaking, Db2 for z/OS-managed data appears in tabular form - i.e., data records appear as rows in tables, and the data fields of a given set of records are columns of the associated table (that is kind of relational database 101 information). Db2 tables are physically instantiated in what are called table spaces (and table spaces map to VSAM data sets - VSAM being the primary file system of the z/OS operating system).

Table spaces fall into the realm of Db2 physical database design, which means they are basically invisible to application programs (a given Db2 table will look the same to a program, regardless of the type of table space in which it resides). DBAs decide on the type of table space that will be used for a given Db2 table.

For many years, there were three Db2 table space types: simple, segmented and range-partitioned (for the latter, partition ranges were initially defined by way of an index - starting with Db2 Version 8 for z/OS, range-partition specifications could be made at the table level). Db2 9 for z/OS (2007) introduced a new category of table space, known as universal. There are two universal table space types: partition-by-growth (PBG) and partition-by-range (PBR). For a PBG table space, a DBA determines an appropriate partition size (known as a data set size) and an appropriate maximum number of partitions (which can later be adjusted if need be), and when the first partition fills up then Db2 automatically allocates another partition, and when that one fills up another partition is allocated, and so on. For a PBR table space, a DBA determines the appropriate number of partitions and the partitioning key (comprised of one or more of tha associated table's columns), and the limit key value for each partition - Db2 then assigns rows to partitions accordingly.

Some noteworthy characteristics of universal table spaces:
  • They are always partitioned (though a PBG table space might never grow beyond its first partition).
  • They are segmented (referring to an aspect of management of the space within the table space - this is why I often use the phrase "traditional segmented" to refer to the segmented table space type that existed before universal table spaces were introduced).
  • A given universal table space can hold one and only one table.

What does Db2 13 have to do with this?

For a Db2 12 system to be migrate-able to Db2 13, function level V12R1M510 has to be activated for the Db2 12 system. Activating function level N for a Db2 for z/OS system means that functionality associated with function levels prior to N will also be activated (if the prior function levels had not been explicitly activated previously). That means that activation of Db2 12 function level 510 will mean activation of the functionality of function level V12R1M504, and there's the rub - or so the aforementioned Db2 administrator thought. What this administrator knew - and knew rightly - is that, with function level V12R1M504 or higher activated, non-universal table spaces go into "deprecated" status (meaning that there will no longer be functional enhancements related to those non-universal table space types, and that the use of such table space types could eventually become not-possible - an eventuality likely to be far in the future and preceded by way-in-advance notice). Of more immediate concern to the Db2 administrator: he was under the impression that non-universal table spaces could not be created in a Db2 13 environment, and given that impression he was thinking that non-universal table spaces in his environment had to be converted to universal table spaces before Db2 12 systems could be migrated to Db2 13.

I had some good news for the Db2 administrator: non-universal table spaces CAN be created in a Db2 13 environment (this actually applies to traditional segmented table spaces - simple table spaces, while still usable even in a Db2 13 environment, have not been CREATE-able since Db2 9). To create a traditional segmented non-universal table space in a Db2 13 system (or in a Db2 12 system with function level V12R1M504 or higher activated), all one has to do is issue the CREATE TABLESPACE statement via a Db2 package executing with an application compatibility level of V12R1M503 or lower (as explained in an entry I posted to this blog a few years ago). The really important point here is that the presence of non-universal table spaces in your Db2 for z/OS environment should in no way impact your Db2 13 migration plans. Is it good to convert non-universal table spaces to the universal variety? Yes (as explained below); however, you do NOT need to complete that table space comversion work prior to migrating your Db2 12 systems to Db2 13 - you can continue that work in a Db2 13 environment.


Incentives for converting non-universal table spaces to universal table spaces

Avoiding use of deprecated table space types is a good reason to move away from simple and traditional segmented table spaces. There are, in addition, positive incentives for making this move, in the form of Db2 for z/OS features that apply only to universal table spaces (and tables therein):
  • Pending DDL - Many changes to database objects can be accomplished via ALTER and a subsequent online REORG of the related table space.
  • LOB in-lining - For a table with one or more LOB (large object) columns, this refers to the ability to store a portion of LOB values (up to a specified length for a given LOB column) in the base table, with the rest of the value (if any) going in the appropriate auxiliary table in a LOB table space.
  • XML multi-versioning - For a table with one or more XML columns, this Db2 feature provides better concurrency for XML data access, and supports the XMLMODIFY built-in function, enabling changes that affect only part of a stored XML data value.
  • ALTER TABLE with DROP COLUMN - This is a pending DDL change (see the first item in this list).
  • Ability to insert a new partition in the middle of a range-partitioned table space (versus having to add the new partition at the end of the table space).
  • The option of making ALTER COLUMN actions pending DDL changes (as opposed to requiring that these be immediate changes).
  • Relative page numbering for range-partitioned table spaces.

How disruptive is it to go from a non-universal to a universal table space?

Answer: about as minimally disruptive as could be. It's an ALTER + online REORG action, so the only period of data unavailability related to a non-universal-to-universal table space conversion would be during the "switch" phase at the end of an online REORG, and that can be as brief as a few seconds. Dependent Db2 packages (related to programs that issue so-called static SQL statements targeting a table in a table space converted from non-universal to a universal type) will be invalidated by the online REORG that materializes the table space conversion - you would subsequently either rebind those invalidated packages with explicit REBIND PACKAGE commands, or you would let Db2 auto-bind them (auto-bind is triggered by the first request by a program to execute an invalidated package).

Converting a table space from non-universal to universal is really easy when the non-universal table space holds a single table. If the non-universal table space is of the simple or traditional segmented variety, the process is: 1) ALTER the table space with a MAXPARTITIONS value, and 2) execute an online REORG of the table space. Following completion of the online REORG, the table that had been in a simple or traditional segmented table space will be in a universal partition-by-growth table space. If the non-universal table space is of the range-partitioned type, the process is similarly simple: 1) ALTER the table space, this time with a SEGSIZE value, and 2) execute an online REORG of the table space. Following completion of the online REORG, the table that had been in a non-universal range-partitioned table space will be in a universal partition-by-range table space.

For a simple or traditional segmented table space that contains multiple tables, conversion to universal is a somewhat more involved process, but it still comes down basically to ALTER and online REORG. The process, introduced with Db2 12 function level 508, is described in an entry I posted to this blog not long ago.


After a table space has been converted from non-universal to a universal type, is it necessary to change the APPLCOMPAT value for Db2 packages that are dependent on the table space (or the table therein)?

Answer: NO. The requirement for a Db2 application compatibility level of V12R1M503 or lower is ONLY relevant for the package (maybe a SPUFI or a DSNTEP2 package, or a package associated with another program or tool used by Db2 DBAs) through which a CREATE TABLESPACE statement is issued, when there is a need to create a traditional segmented (i.e., non-universal) table space in a Db2 13 environment or a Db2 12 environment in which the activated function level is V12R1M504 or higher. Db2 packages having any supported APPLCOMPAT value can access a table in a universal table space (the lowest supported APPLCOMPAT value is V10R1, and the highest possible APPLCOMPAT value is equivalent to the current activated function level of the Db2 for z/OS system in which the package executes).


In a nutshell...

Converting non-universal table spaces to universal types is something you ought to be doing, but you DO NOT have to get that conversion work completed prior to migrating a Db2 12 system to Db2 13. The conversion process - available in Db2 12 and Db2 13 environments - varies somewhat depending on whether the non-universal table space is range-partitioned or not, and on whether the non-universal table space (if not range-partitioned) holds one table or multiple tables, but in any case it is pretty straightforward, minimally disruptive and application-transparent. So, yes, work on this, but at a pace that works for you and for your organization.

Friday, August 23, 2024

After Migrating to a New Version of Db2 for z/OS, Rebind All Your Plans and Packages

At this writing, a lot of Db2 for z/OS-using organizations are actively engaged in migrating to Db2 13 from Db2 12, and plenty of sites have recently gotten to Db2 13. That being the case, it seems like a good time to remind people of an important step to take after migrating to Db2 13, while still at the V13R1M100 function level (the initial Db2 13 function level when you've migrated from Db2 12): rebind all your plans and packages.

First: why do this? For a couple of reasons. One would be to get a CPU efficiency benefit. The other has to do with the benefit of keeping package code current (I'll explain that "code" reference momentarily). Let me expand on both these rebind motivations.


Package REBIND motivation #1: improved CPU efficiency

Rebinding packages when you get to a new version of Db2 for z/OS can deliver CPU efficiency benefits in two ways. First (for packages associated with programs that issue static SQL statements), it lets the Db2 optimizer generate access paths for queries (and for "searched" UPDATEs and DELETEs - i.e., UPDATE and DELETE statements that have predicates) using options that may not have been available to the optimizer in the previous version of Db2. In some cases, new access path options can substantially improve a query's performance.

What if you're happy with the current access plan for a package (very often the case)? That brings us to the second source of CPU efficiency gain typically associated with a package rebind in a new-version Db2 environment: even when access paths don't change as a result of a REBIND (and they generally won't when you issue REBIND PACKAGE with the option APREUSE(WARN) or APREUSE(ERROR), which tells Db2 to re-use existing access paths for the package's SQL statements), it's quite likely that the rebind of a package in a new-version Db2 environment will yield at least some improvement in the CPU efficiency of package execution. How is that so? Well, as briefly mentioned above, a Db2 package contains executable code. For a package related to a program that utilizes static SQL, part of the package's executable code will be, in essence, the compiled form of the static SQL statements. See, there is no z/OS or IBM Z instruction called (for example) SELECT. A SELECT statement (or any other SQL statement) embedded in a Db2-accessing program has to be turned into code that can be executed in the z/OS system. That executable-form SQL is found in the program's Db2 package (itself originally generated from a BIND of the program's static SQL statements). And here's the thing: the IBM Db2 for z/OS development team is always working to "tighten up" executable-form SQL (i.e., to make the executable form of SQL statements ever more CPU-efficient). When you let Db2 13 re-generate the code in a package by rebinding that package, you typically will get some CPU efficiency benefit from the resultant "tightened up" code that Db2 13 can deliver - again, even when access paths for the package's SQL statements don't change.


Package REBIND motivation #2: package code currency

Efficiency benefits of tightened-up package code aside, there is another reason to let a new version of Db2 for z/OS regenerate the code for your packages via REBIND: it makes the package code more current in the sense that it is associated with the newer version of Db2. Why is that important? Because at some point too-old package code (i.e., code generated for a package via BIND or REBIND with an older version of Db2) will become un-executable for a newer version of Db2. That was the case in a Db2 12 for z/OS environment for packages last bound or rebound in a pre-Db2 10 system, and it is true in a Db2 13 environment for packages last bound or rebound in a pre-Db2 11 system (that is why activation of Db2 12 function level 510 - a prerequisite for migration to Db2 13 - will not be successful if you have any pre-Db2 11 packages still in use in your Db2 12 environment). If you keep your Db2 package code current by rebinding packages when you go to a new version of Db2, this issue of eventually-not-executable package code will be something about which you won't have to worry.


Good Db2 13 news regarding REBIND PACKAGE with APREUSE(WARN) or APREUSE(ERROR)

As I mentioned previously, it's often the case that a Db2 DBA team is fine with package access paths being what they are. In such situations, when doing a large-scale rebind of packages upon migrating to a new version of Db2, it makes sense to specify APREUSE(WARN) or APREUSE(ERROR) in the REBIND PACKAGE commands. Both forms of APREUSE tell Db2 to reuse existing access paths for a package's SQL statements, versus generating new access paths. The difference? With APREUSE(WARN) in effect, if Db2 cannot re-use an access path for one or more of a package's SQL statements, the rebind will go forward and Db2 will issue an information message about the access path change and will write information to EXPLAIN tables that will allow you to see just what changed. With APREUSE(ERROR) in effect, a REBIND PACKAGE action will fail if Db2 cannot reuse all access paths associated with a package's SQL statements.

Here's the good Db2 13 news regarding APREUSE(WARN) and APREUSE(ERROR):

  • The CPU efficiency of REBIND PACKAGE when APREUSE(WARN/ERROR) is specified has been improved, so a large-scale rebind with these specifications will consume less CPU time.
  • The rate of warnings, when APREUSE(WARN) is used, or errors, when APREUSE(ERROR) is used, should be lower in a Db2 13 system versus previous Db2 environments. In other words, the rate of success for access path reuse in a Db2 13 environment should be higher versus previous Db2 environments.

A word about APPLCOMPAT

When you do a large-scale rebind of packages after migrating to Db2 13, do you need to change the APPLCOMPAT value for your packages? No, you do not need to do this. As is the case for a Db2 12 system, in a Db2 13 environment APPLCOMPAT values as low as V10R1 are OK. Additionally, you should know that the CPU benefit of package rebind that I described previously does NOT require going to a higher APPLCOMPAT value when rebinding packages; and, if you want to let the Db2 13 optimizer utilize new access path options, by not using APREUSE(WARN) or APREUSE(ERROR) in a REBIND PACKAGE command, this does NOT require specification of a higher APPLCOMPAT value for the package in question - query optimization is unrelated to a package's APPLCOMPAT value.

If you'd prefer to take package APPLCOMPAT values higher when rebinding packages in a Db2 13 environment, go ahead and do that - just know that this is an option, and not a technical requirement.

A little more information here:

  • When a package is rebound and the REBIND PACKAGE command does not include an APPLCOMPAT specification, by default Db2 will just preserve the package's existing APPLCOMPAT value.
  • You can learn more about APPLCOMPAT via a part 1 and part 2 entry I posted to this blog a few years ago.

Remember that rebind phase-in will help you out

Rebind phase-in functionality, introduced with Db2 12 function level 505 and part of the Db2 13 base code, can be a BIG help when you're looking to rebind all of your packages following migration to Db2 13. How so? By eliminating REBIND contention with in-use packages. Prior to Db2 12 FL505, you couldn't rebind a package if the package was in-use at the time (i.e., if the package was allocated to a thread for execution), and this caused many REBIND PACKAGE commands to time out (especially if the target package was bound with RELEASE(DEALLOCATE) and allocated to one or more threads of the type that persist through COMMITs). With rebind phase-in functionality in effect (and this is automatic in a Db2 12 FL505 or higher environment, or in a Db2 13 system, with no special REBIND specification required), a REBIND package action will succeed even if the specified package is in-use at the time, and the rebind itself will not disrupt a related application workload.

Rebind phase-in functionality can be particularly helpful for rebinding packages that are very high-use in nature, as is often the case for (among others) the IBM Data Server Driver / Db2 Connect packages (referring to the packages whose default collection is the one named NULLID). At sites with high-volume, round-the-clock Db2 DDF (i.e., client-server) workloads, rebinding the NULLID packages could be a real challenge. Rebind phase-in removed that challenge.

NOTE: rebind phase-in functionality requires that the value of the Db2 ZPARM parameter PLANMGMT be set to EXTENDED. As that has long been the default value for PLANMGMT, it's probably the setting for your Db2 for z/OS systems, but you might want to double-check that.


Rebind plans, too - and note some distinctions versus packages

Yes, plans - as well as packages - should be rebound following a migration to Db2 13, but there are some difference versus packages that you should consider.

First, plan rebinds apply exclusively to your "local-to-Db2" applications, such as CICS-Db2 or IMS-Db2 transactions, or Db2-accessing batch jobs - DDF-using applications are not associated with Db2 plans in a technical sense (the DISTSERV plan related to DDF-using applications is for reporting and instrumentation purposes - it's not a Db2 plan in the technical sense).

Second, rebinding of plans when you get to Db2 13, while recommended, is not as high-priority an action as is rebinding of packages. Plans don't contain code that provides the executable form of SQL statements - it has been a LONG time since you were able to bind SQL statements directly into plans, and existing plans containing compiled SQL statement code had to be converted to package-related plans years ago (a Db2 plan points to one or more collections of packages that are executed by applications that utilize the plan). This being the case, you'll be more in take-your-time mode when it comes to rebinding plans in the Db2 13 environment, and that relatively diminished level of urgency is helpful in light of the fact that there is currently no plan-related equivalent of the phase-in functionality used for package rebinds.

Given that there can be contention when a REBIND PLAN command targets an in-use plan, timing can be important. For rebind of a plan used by a batch application, it generally won't be hard to find a time window during which the batch application is not running. Even if you have a round-the-clock transaction (CICS or IMS TM) that accesses Db2 for z/OS, you should be able to successfully execute a REBIND PLAN if you issue the command during a time of lower transaction volume and if the plan in question is not bound with the RELEASE(DEALLOCATE) option (in my experience, RELEASE(DEALLOCATE) is typically used for certain packages, and not for plans). If RELEASE(DEALLOCATE) is in effect for a plan you want to rebind, and that plan is associated with a round-the-clock transaction workload, and the plan is allocated to persistent threads (e.g., CICS protected threads or IMS WFI or pseudo-WFI threads), you might need to look at briefly going with non-persistent threads for the workload to enable successful execution of REBIND PLAN.


Summing it up

Rebinding your Db2 plans and packages after going to Db2 13 (while still at the V13R1M100 function level) should be part of your overall Db2 13 migration plan. Taking this action should yield some CPU efficiency gains (even when access paths for static SQL packages don't change), and the boost in package and plan code currency will help to facilitate migration to the version of Db2 that follows V13 (whenever "Vnext" makes the scene).

Tuesday, July 30, 2024

Db2 for z/OS: What Makes for a Balanced Mainframe Configuration?

What I'm writing about today is something I've been talking about for years, thought often in a somewhat indirect way. It has to do with mainframe memory (often referred to as "real storage" by z/OS people, to distinguish it from virtual storage) - more specifically, what it takes, memory-wise, to have what I'd call a balanced configuration for a z/OS LPAR (a z/OS LPAR, or logical partition, is a z/OS system; Db2 for z/OS runs within a z/OS LPAR, and a given mainframe "box" could house one or more z/OS LPARs). After working this year with a couple of situations involving z/OS LPARs with not-well-balanced configurations, I think it's time to address the topic directly.

I'll tell you right off that the gist of the matter is this: to realize the full productive potential of a z/OS LPAR's processing capacity, that capacity has to be balanced by an appropriate amount of system memory.

It's at this point that an IT person who administers so-called distributed systems servers (Linux, UNIX or Windows servers) could be expected to say, "Duh." See, distributed systems administrators have talked about "balanced configuration units" (aka BCUs) for many years (when I was in the IT organization of a financial services company back in the early 2000s, I regularly saw references to BCUs). The BCU concept was simple and straightforward: a distributed systems server with X number of processor cores should have at least Y amount of memory (BCU, in this context, often extended to disk storage, as well - that's not so much the case with z/OS systems, owing in large part to the architecture of the z/OS I/O subsystem).

Oddly enough, I generally didn't hear much talk about balanced configurations among z/OS people. In fact, back around 2008 or so things started to get more un-balanced at some z/OS sites. That was when IBM delivered the z10 line of mainframe servers, a line that pretty dramatically increased processing power relative to its predecessor. What then happened in more than a few instances is that z/OS LPAR processing capacity raced ahead of real storage resource growth. Why did this happen? I'm not certain, but one possibility is the fact that IBM Z (the official product designation for mainframe servers) and z/OS were a bit late to the 64-bit party, referring to 64-bit addressing, which hugely expanded virtual storage resources (to 16 exabytes, from the 2 gigabyte limit imposed by 31-bit addressing) and offered, as well, access to vastly larger real storage resources. z/OS system administrators had for years worked hard to fit huge mainframe workloads into virtual and real storage spaces that could not exceed 2 GB, and when enormously large real storage resources became a possibility, it seemed to me that there was almost a reluctance on the part of some z/OS systems people to ask for more memory than they'd used before. Maybe people felt that requesting a lot more memory for a z/OS system was akin to "taking the easy way out" by just "throwing hardware at the problem" of keeping up with application workload demands.

Distributed systems people had no such qualms about requesting lots of memory to go with lots of processing power.

Anyway, at a number of z/OS sites things got pretty rough with regard to delivering required levels of application performance and throughput because of a lack of real storage resources, and these issues could be particularly acute for z/OS systems supporting Db2 for z/OS workloads. Why is that? Because Db2 for z/OS, from the beginning, was architected to take advantage of large virtual and real storage resources. See, when Db2 for MVS (as it was originally known) was announced back in 1983 (as I recall - it was the second year of my first stint with IBM), the MVS/ESA operating system was right around the corner - and with it, Db2 for MVS/ESA. MVS/ESA provided 31-bit addressing, taking the old 16 megabyte virtual and real storage limit (can you believe that?) associated with 24-bit addressing up to a then-astounding 2 gigabytes. That great big increase in addressability allowed the buffering of large amounts of Db2 data in memory, and that was a huge factor in generating the performance that helped Db2 become a tremendously popular DBMS for z/OS systems (the "We have liftoff" for Db2 moment came when its performance capability matched the huge programmer productivity boost associated with SQL and the relational database model, both of which IBM invented).

Fast-forward lots of years, and you get to that time - starting around the late 2000s, by my reckoning - when, as noted, z/OS processing capacity got seriously out in front of real storage resources at a number of Db2 for z/OS sites. What this sometimes meant for those sites: either the Db2 buffer pool configuration was much smaller than it should have been, due to the lack of real storage for the z/OS LPAR, resulting in very high read I/O rates that impeded application throughput and increased CPU consumption; or, the Db2 buffer pool configuration - while still perhaps on the small side - was too big relative to the undersized real storage resource, leading to elevated levels of demand paging in the z/OS system, with resultant adverse impacts on performance (a production z/OS LPAR's demand paging rate, available via an IBM RMF CPU Summary report, should be less than 1 per second). Plenty of organizations have acted in recent years to get real storage in line with processing capacity for their Db2-containing z/OS LPARs, but quite a few still have production Db2 for z/OS subsystems running in z/OS LPARs that are under-configured from a real storage perspective. It's a good time to achieve balance for Db2-related z/OS LPARs that currently have too little system memory.

OK, so what does a balanced configuration look like for a z/OS LPAR in which a production Db2 subsystem runs? My rule of thumb, based on years of reviewing performance data for production Db2 for z/OS systems, is this: the z/OS LPAR should have at least 20 GB of real storage per engine (i.e., per processor) - and that's regardless of the mix of general-purpose and zIIP engines configured for the LPAR. Here's an example: suppose you have a z/OS LPAR, in which a production Db2 subsystem runs, that is configured with 5 general-purpose and 3 zIIP engines. I'd say that to effectively balance that LPAR's processing capacity with real storage, you'd want the LPAR to have at least 160 GB of real storage (8 engines X 20 GB - at least - per engine). I'm emphasizing "at least" because you don't need to stop at 20 GB of real storage per engine. Some Db2 for z/OS-using organizations have production z/OS systems with 30 GB, 40 GB, 50 GB or more of real storage per engine. Is that over-doing it? Not in my view. These organizations have done things like super-sizing buffer pools; going big for other performance-relevant Db2 memory areas such as the package cache, the database descriptor cache, the prepared dynamic statement cache, the sort pool and the RID (row ID) pool; and boosting the use of RELEASE(DEALLOCATE) packages combined with persistent threads (i.e., Db2 threads that persist across commits) - a move that, like the others, ups Db2's memory usage and drives down per-transaction CPU consumption. The point: give Db2 for z/OS enough memory, and it will perform very well. Give it even more memory, and it will perform even better.

[Here's an important cost factor to consider: upping the real storage resource for a z/OS LPAR will not cause software costs to increase for the LPAR. z/OS software costs are based on general-purpose processor utilization, not real storage size.]

You don't have to take my word on the importance of large memory resources for the performance of a Db2 for z/OS system - just look at the trend lines:

  • z/OS LPAR real storage sizes are in fact getting steadily larger over time, driven in large part by positive results achieved through leveraging big memory for improved Db2 for z/OS workload performance and CPU efficiency (and fueled as well by the continuing drop in the cost of mainframe memory on a per-gigabyte basis). Reference point: the largest real storage size I've seen with my own eyes for a z/OS LPAR in the real world (versus an IBM performance benchmark system) is 2.4 terabytes. The Db2 for z/OS subsystem running in that LPAR has a buffer pool configuration size (aggregate size of all allocated buffer pools) of 1.7 TB, and the LPAR's demand paging rate is zero (the 700 GB of real storage beyond the Db2 buffer pool configuration size is more than enough for the rest of the system's storage requirements).
  • z/OS 3.1 (the current version of the operating system) provides support for up to 16 terabytes of real storage for one z/OS LPAR (up from 4 TB previously). Caveat: with the current packaging of memory for the IBM z16 line of mainframe servers, it's recommended that you not go beyond 10 TB of real storage for a single z/OS LPAR - that restriction will likely be gone at a future time.
  • Since Db2 12 for z/OS (the current version is Db2 13), a single Db2 subsystem can have a buffer pool configuration size of up to 16 TB (that's a prep-for-the-future thing - you generally want your buffer pool configuration size to be less than the real storage size of the associated z/OS LPAR, and as noted that size is currently limited to 16 TB, with a recommended maximum of 10 TB for an LPAR on a z16 server).
  • Multiple virtual storage-related (and, therefore, real storage-related) Db2 for z/OS configuration parameters (known as ZPARMs) have default values for Db2 13 that are substantially greater than the corresponding Db2 12 values. These parameters include those that specify the size of the package cache, the database descriptor cache, the sort pool and the log output buffer. The substantially larger default values for these parameters in a Db2 13 environment reflect the awareness of the IBM Db2 for z/OS development team that z/OS LPAR real storage sizes are getting larger in an ongoing way, and a reaffirmation that leveraging larger real storage resources is a winner for Db2 performance and CPU efficiency.
If you have a Db2-housing z/OS LPAR that is under-configured in terms of real storage, do what you can to change that situation. Yes, when 2 GB was the real and virtual storage limit (the latter referring to the address space size limit) for z/OS systems, Db2 for z/OS people went to heroic lengths to push huge transaction rates through LPARs that were very much memory-constrained. That was then. These days, no one gets a medal for "doing the best you can" with a Db2 for z/OS system that is sorely lacking in the real storage department. Take a cue from your peers on the distributed systems side of the house. Memory matters.

Wednesday, June 26, 2024

Db2 for z/OS: Getting From Function Level 500 to 510 in a Db2 12 Environment

It's pretty well known that getting the activated function level of a Db2 12 for z/OS system to V12R1M510 is required prior to migrating that Db2 12 system to Db2 13 (I blogged about that a couple of years ago). At present (June, 2024), there are still a good number of sites running Db2 12 for z/OS with an activated function level of V12R1M500. I sometimes get, from people at such sites, a question like this: "How should we go from Db2 12 function level 500 to function level 510?" Generally speaking, what these folks are wanting is for me to opine on going straight from Db2 12 function level 500 to function level 510, versus getting from FL500 to FL510 by first going to some "in-between" function level and then going to 510. In this blog entry, I'll tell you what I tell people who ask me this "getting from A to B" question.

Right off the bat, I'll say that I'd be comfortable with either approach - in other words, there is not a "right" and a "wrong" way to go from Db2 12 FL500 to FL510. Let's consider first the "one fell swoop" approach of going straight from Db2 12 FL500 to FL510. What is required, in a technical sense, to do this? The code level of the Db2 12 system (which you can check using the output of the Db2 command -DISPLAY GROUP) has to be 121510. The catalog level (also check-able with -DISPLAY GROUP) has to be V12R1M509 (there is no 510 catalog level; and, you can use the CATMAINT utility to take the catalog level to V12R1M509 if it is not already there). Additionally, you can't have any packages that have been executed within the past 1.5 years that were last bound or rebound prior to Db2 11 (this "no pre-Db2 11 still-in-use packages" requirement is explained in the aforementioned blog entry about preparing to migrate from Db2 12 to Db2 13).

Let's say those technical prerequisites are in-place. Given that you could, in that case, go straight from Db2 12 FL500 to FL510, why wouldn't you? What would hold you back? In my experience, the chief concern is often something like this: "If we make the big jump from Db2 12 FL500 to FL510, I'm afraid that will mess up some of our Db2-accessing applications."

That concern, though understandable, is essentially unfounded if you don't change package APPLCOMPAT values when making the big jump in the activated function level of the Db2 12 system. I've written plenty about APPLCOMPAT, including a part 1 and part 2 entry in this blog. The important thing to remember about APPLCOMPAT, in relation to a change in the activated function level of a Db2 system, is this: a package's APPLCOMPAT value can serve to insulate an associated application program from SQL behavioral changes that could be introduced via a change to a higher activated function level in a Db2 for z/OS environment. Let's unpack that statement. A SQL behavioral change - referred to in the Db2 for z/OS documentation as a "SQL incompatibility" - can be succinctly described thusly: same SQL, same data, different result. That might sound kind of alarming. Here's the two-pronged good news: 1) SQL incompatibilities are quite few and far between (they are documented whenever they are introduced by a new Db2 for z/OS version or function level), and 2) they tend to affect either very few or none of an organization's Db2-accessing applications (they are usually associated with highly specialized, often unusual scenarios).

Now, while it's highly unlikely that any of an organization's Db2-accessing programs would be negatively impacted by a SQL incompatibility associated with a newer Db2 function level, I can't say that the risk of application impact related to a change in activated Db2 function level is zero if applications are exposed to SQL behavioral changes. That's where APPLCOMPAT comes in. See, if the Db2 package used by an application program has an APPLCOMPAT value of (for example) V12R1M100, SQL behavior for that program will be that of a Db2 12 system with function level 100 activated, even if the Db2 environment in which the program is executing has an activated function level of V12R1M510 (or V13R1M100 or some other Db2 13 function level, after the system has been migrated to Db2 13). That is how APPLCOMPAT insulates a Db2 application program from SQL behavioral changes that might be introduced when a higher function level is activated for the Db2 system in which the program's SQL statements execute. So, make a jump in activated function level from 500 to 510 in your Db2 environment, and leave package APPLCOMPAT values as they are, and your Db2 application programs will be (conceptually speaking) unaware of the environmental change.

OK, so I'd be plenty comfortable in taking a Db2 12 system's activated function level from 500 right to 510, and I hope you'd be similarly comfortable with such a move. You might find, however, that "selling" the powers that be on a plan for getting to Db2 12 FL510 from FL500 would be easier if that plan included a "rest stop" at a function level between 500 and 510. If that were the case, you could go that route and not lose any honor in my eyes; and, yours wouldn't be the first Db2-using organization to take the 2-step approach for getting from Db2 12 FL500 to FL510. I can tell you that a pretty popular intermediate stop on the way from Db2 12 FL500 to FL510 is FL505. This is true for a couple of reasons: stopping for a while (for however long makes people comfortable: a few weeks, a couple of months - whatever) right between FL500 and FL510 appeals to some folks. Additionally, Db2 12 FL505 makes available to you one of my favorite Db2 12 features: rebind phase-in.

Alright, to sum up: if your organization has been sitting at Db2 12 FL500 for a long time, and you want to get to FL510 so you can go from there to Db2 13, consider taking one of two routes from A to B:

  • Straight through - If your code level and catalog level and no-still-in-use-pre-Db2-11-packages ducks are all in a row, go from Db2 12 FL500 straight to FL510, keeping in mind that leaving package APPLCOMPAT values as they are is a way to insulate Db2-accessing programs from any impact related to the Db2 environmental change.
  • Go part way, sit a spell, then go the rest of the way. As noted, Db2 12 FL505 is a popular rest stop en route from FL500 to FL510.
The main point is, GET THIS DONE. Db2 12 goes out of service after December 31, 2025. You still have plenty of time to get to Db2 12 FL510 and then on to Db2 13, but if you sit back too long you could end up feeling a little anxious about the whole thing. Who needs that? I hope information in this blog entry will help you get your organization's Db2 12-to-13 show on the road.

Thursday, May 30, 2024

Db2 for z/OS: Really Big Buffer Pools are Great, but Don't Stop There

 Back in 2018, I reviewed an organization's production Db2 for z/OS environment, and saw at that time the largest z/OS LPAR real storage size I'd ever seen: 1100 GB. The Db2 subsystem running in that LPAR had (not surprisingly) the largest buffer pool configuration I'd ever seen: 879 GB (referring to the aggregate size of all of the Db2 subsystem's buffer pools). Within that buffer pool configuration was (again, not surprising) the lagest single Db2 buffer pool I'd ever seen: approximately 262 GB (66,500,000 4K buffers).

Those "biggest I've ever seen" figures sustained that status until just recently, when I reviewed another production Db2 for z/OS system. The new "biggest I've ever seen" numbers are way larger than the previous maximums:

  • A z/OS LPAR with 2.4 terabytes of real storage
  • A Db2 subsystem with 1.7 terabytes of buffer pool resources.
  • An individual buffer pool of approximately 560 GB in size (140,000,000 4K buffers)
What I saw is great, and it's the future, folks. That humongous buffer pool configuration is eliminating a humongous number of read I/Os (synchronous and asynchronous), and that, in turn, boosts CPU efficiency and throughput for the Db2-accessing application workload. z/OS LPAR real storage sizes are getting bigger and bigger, in part because mainframe memory keeps getting less expensive on a per-GB basis, and in part because z/OS can utilize ever-larger amounts of real storage (z/OS 3.1 supports up to 16 TB of memory for one LPAR - though with the way memory is currently packaged on an IBM Z server, you're advised to limit the size of one LPAR's real storage resource to 10 TB), and in part because loading up on real storage does not increase the cost of software that runs in a z/OS system (the cost of that software is based on mainframe general-purpose CPU utilization - not real storage size).

Organizations that run production Db2 subsystems in z/OS LPARs that have large amounts of real storage are increasingly going with really large Db2 buffer pool configurations. That's a smart thing to do. Db2 allows for up to 16 TB of buffer pool space for a single subsystem, and going big is a definite plus for Db2 workload performance and CPU efficiency (just be sure that you don't over-burden a z/OS LPAR's real storage resource: you want to keep the LPAR's demand paging rate - available via an RMF Summary report - below 1 per second).

Here's the point I want to make with this blog entry: while really big buffer pools are great for Db2 application performance, don't focus solely on the size of a Db2 subsystem's buffer pool configuration. In addition to going big, take other steps to maximize the positive performance benefits of a large Db2 buffer pool configuration:

  • Use large real storage page frames for the busier buffer pools - In my view, a buffer pool's GETPAGE rate (obtainable from a Db2 monitor-generated statistics long report) is the best indicator of a pool's busy-ness. My recommendation is to use large real storage page frames for every pool that has a GETPAGE rate (during a busy hour of the processing day) in excess of 1000 per second. Large real storage page frames enhance CPU efficiency for page access by reducing the CPU cost of translating virtual storage addresses to real storage addresses. Some related things to note:
    • Page-fixing of buffers in a pool is a prerequisite for using large real storage page frames - This is done for a pool via a specification (in an -ALTER BUFFERPOOL command) of PGFIX(YES). Note that actually changing from not-page-fixed to page-fixed requires deallocation and reallocation of a pool - this usually happens as a consequence of recycling (i.e., stopping and then restarting) the associated Db2 subsystem. That deallocation and reallocation is also required to go from the default real storage frame size of 4K to a larger frame size.
    • Use the appropriate real storage frame size - For a buffer pool that is at least 20 GB in size (a little over 5,000,000 buffers, if we're talking about a 4K pool), I recommend the use of 2 GB page frames (this is accomplished via a specification of FRAMESIZE(2G) in an -ALTER BUFFERPOOL command). For a pool that is smaller than 20 GB, I recommend the use of 1 MB page frames (FRAMESIZE(1M)). Note that if a pool is defined with PGSTEAL(NONE) (see below for information about such pools, which are known as "contiguous" pools), 2 GB frames cannot be used - you need to go with FRAMESIZE(1M) for a PGSTEAL(NONE) pool, unless objects assigned to the pool are quite small (e.g., less than 100 4K pages), in which case the default 4K frame size would be appropriate (for a PGSTEAL(NONE) pool, Db2 will use a given large real storage page frame for buffers that hold pages of one object assigned to the pool).
    • Set the value of the z/OS parameter LFAREA appropriately - LFAREA, a parameter in the IEASYSnn member of the z/OS data set named SYS1.PARMLIB, specifies the amount of a z/OS LPAR's real storage resource that is to be managed in 1 MB (and, possibly, 2 GB) frames. I generally like to see an LFAREA specification that provides enough 1 MB (and 2 GB, when appropriate) frames to fully back FRAMESIZE(1M) (and, if relevant, FRAMESIZE(2G)) pools, but not much more than that. Why not much more? Because a lot of processes in a z/OS system can only use 4 KB page frames. If you think you might want to later enlarge some Db2 buffer pools that have a FRAMESIZE(1M) or a FRAMESIZE(2G) specification, you can make the LFAREA value for the frame size in question larger than you need at present - just don't go overboard with that.
    • Use the output of the Db2 command -DISPLAY BUFFERPOOL(ACTIVE) DETAIL to verify that pools that have a preferred frame size of 1M or 2G are fully backed by frames of the desired size - If you see, in the output of that command, that a pool with a VPSIZE of 100,000 buffers and a preferred frame size of 1M has 70,000 buffers allocated in 1M frames and 30,000 buffers allocated in 4K frames, it means that there aren't enough 1 MB frames in the system to fully back the pool. Note that for a pool that has a preferred frame size of 2G, you might see some buffers allocated in 1M frames, even if the system has enough 2 GB frames to "fully" back the pool. Why might that be the case? Well, in the interest of not wasting a lot of space in a 2 GB page frame, Db2 won't use such a frame if it can't fill at least about 95% of the frame with buffers. Suppose you have a pool that is about 41 GB in size. Db2 will use twenty 2 GB frames for that pool, and the remaining 1 GB of buffers will be allocated in 1 MB frames, As far as I'm concerned, that is not at all a big deal. No problem.

  • If you have any PGSTEAL(NONE) buffer pools, aim for zero activity in the overflow area of those pools - A PGSTEAL(NONE) buffer pool is also known as a "contiguous" buffer pool. Such a pool is intended to be used to completely cache in memory the objects assigned to the pool. A contiguous buffer pool can optimize efficiency for page access, but some of that advantage is lost if there is any activity in the pool's overflow area, which is where any buffer stealing would occur (if the pool were in fact not large enough to hold every page of every object assigned to the pool). Output of the Db2 command -DISPLAY BUFFERPOOL (ACTIVE) DETAIL will show if there is any activity in the overflow area of a PGSTEAL(NONE) pool. If you see that there is activity in the overflow area of a PGSTEAL(NONE) pool (unless it's a really small amount of activity), either take one or more objects out of the pool (by reassigning them to other pools) or make the pool larger (always keeping in mind that you want the demand paging rate of the z/OS LPAR to be less than 1 per second - don't over-burden the LPAR's real storage resource).
And there you have it. For a Db2 for z/OS buffer pool configuration, really big is really great, but take the time to go the extra mile by optimally configuring the pools in the configuration.

Monday, April 29, 2024

Db2 13 for z/OS: Utility Execution History

 A few months ago, I got this question from a Db2 for z/OS DBA: "Is there a way we can check to see if the UNLOAD utility has been executed for certain of our tables?" The environment in question was a Db2 12 for z/OS system, and because of that I had to provide an answer that was less-than-great from an ease-of-use persepective: "Yes, you can do that in a Db2 12 environment, but the process is going to be a bit cumbersome. You could set up a Db2 audit policy that would record utility execution. What that will do is cause Db2 to write certain trace records when utilities are executed. You'd need to use your Db2 monitor to format that trace information into a human-readable report (using IBM's OMEGAMON monitor for Db2 for z/OS, that would be by way of a Record Trace report); and, you'd have trace records written for EVERY utility execution during the reporting time interval - potentially, a lot of data to sift through; and, there would be trace records generated for every utility executed for ANY database object - not just the tables in which you're interested (more data to sift through)."

"Alternatively, you could set up a different audit policy that would limit trace output to the tables of interest, but that policy would cause Db2 to generate trace records for ALL operations performed involving that set of tables, whether associated with a utility or with an application process - again, potentially a lot of trace data to sift through."

Not the idea situation, but along comes Db2 13 for z/OS to make things better - in two steps.

Step 1: Once you've activated function level V13R1M501, you can take advantage of a new ZPARM parameter, UTILITY_HISTORY. The default value for that parameter is NONE - not because we (IBM) want to discourage you from using a new Db2 capability; rather, this is in keeping with the traditional approach for a new ZPARM: the initial default value preserves existing behavior. "Existing behavior" in this case is "no utility history," because utility history functionality was not available prior to Db2 13 function level 501. If you set UTILITY_HISTORY to UTILITY, something nice happens: every time a utility executes, Db2 will insert a row into the SYSIBM.SYSUTILITIES table (newly added when CATMAINT is executed to take the catalog to the V13R1M501 level). That row for a utility in SYSUTILITIES provides a lot of useful information, such as:

  • The name of the utility (e.g., UNLOAD, or COPY, or REORG, or ...)
  • The name of the job through which the utility was executed
  • The user ID that invoked the utility
  • The starting point of the utility, both timestamp-wise and logpoint-wise
  • The timestamp at which the utility completed processing
  • The elapsed time for the utility job
  • The general-purpose CPU time and zIIP CPU time for the utility job
  • The portion of CPU time (both general-purpose and zIIP) consumed with sort activity related to the utility job
  • The utility job's return code
  • Whether the utility job was terminated (and, if so, whether it was restarted)
Step 2: After you've activated function level V13R1M504, you can change the value of UTILITY_HISTORY in ZPARM to OBJECT. When you do that, execution of a utility will cause Db2 to insert into SYSUTILITIES a row with the useful informational items noted above, and in addition to that Db2 will insert into SYSIBM.SYSOBJEVENTS a row for each object (non-partitioned table space or index, or a partition of a table space or index) processed by the utility (SYSOBJEVENTS makes its debut when the catalog is taken to the V13R1M504 level).

[Note: prior to activation of function level V13R1M504, there is some capability to obtain information about the object(s) processed by a utility by matching SYSUTILITIES rows with SYSCOPY rows based on values in the EVENTID column which is found in both tables. I say, "some capability," because not every utility drives SYSCOPY insert activity - that's what makes SYSOBJEVENTS important.]

Back to the question, referenced at the start of this blog entry, about tracking UNLOAD activity for certain tables. In a Db2 13 environment with function level V13R1M504 (or higher) activated, and with UTILITIES_HISTORY set to OBJECT in ZPARM, this question can be answered simply by querying SYSUTILITIES with a WHERE NAME = 'UNLOAD' predicate, and joining with SYSOBJEVENTS on the EVENTID column to get the related table space names (and of course if you are wanting to track UNLOAD activity for particular tables you can have a WHERE clause for the SYSOBJEVENTS table that references the name of the table space or table spaces of interest).

[I recognize that UNLOAD can be executed at a table level, and that a table space could have multiple tables, but I'd hope that your sensitive-data tables are in single-table table spaces because 1) it's best to have tables in universal table spaces, and a universal table space is related to a single table; and 2) I think that data protection can be maximized when a sensitive-data table is isolated in its own table space.]

Needless to say, tracking UNLOAD activity is just one of many ways in which Db2 13 utility history data can be beneficially utilized. In section 8.1.7 of the IBM "redbook" titled, IBM Db2 13 for z/OS and More, you'll find examples of queries of SYSUTILITIES that can be used to gather all kinds of helpful information, such as:
  • All the utilities that executed between midnight and 8:00 AM this morning
  • All the utilities that are currently active or stopped
  • All the utilities that finished with a return code of 8 or higher
  • The top general-purpose CPU-consuming LOAD jobs over the past 7 days
  • And more...
Those sample queries can help you get started, and soon you and your teammates will come up with your own queries that yield valuable info on utility execution at your site (and keep in mind that the queries in the above-referenced redbook don't include SYSOBJEVENTS because that catalog table was not yet present when the redbook was written - you can of course extend the queries with joins to SYSOBJEVENTS).

This is a Db2 13 enhancement that I like a lot. I think you'll like it, too. Check it out.

Friday, March 29, 2024

Db2 for z/OS Data Sets: If You're Worrying About Extents, You Can Probably Stop Worrying

Not long ago, a Db2 for z/OS DBA sent to me, via a colleague of mine, a question. He described in an email the procedure that his team regularly used to consolidate extents, when the number of these got into double digits for a Db2 table space-related data set, back down to one. He noted that this extent-consolidation procedure was more time-consuming and CPU-intensive than desired, and he wanted to know if I had any suggestions for making the procedure more efficient. In fact, I did have a suggestion for improving the efficiency of the Db2 data set extent consolidation procedure used at this person's site. My suggestion: STOP DOING THAT.

It might have been the comedian Henny Youngman who'd get laughs with this joke: "I told my doctor, 'It hurts when I do this.' He told me, 'Stop doing that.'" In all seriousness, Henny (or whoever it was) had an important point there. When some procedure causes pain in the form of CPU consumption and/or labor intensity, the best way to take that pain down to zero is to dispense with said procedure. In the context of Db2 data set extent-reduction efforts, my "Stop doing that" suggestion might engender this response: "But, if we dispense with our Db2 data set extent consolidation procedure, we'll end up with Db2 data sets that have a lot of extents!" My response to that response: "So?"

Here's the deal, folks: extents matter WAY less for Db2 for z/OS data sets than they did a long time ago (like, back in the 1990s). Way back when, a real concern about a Db2 table space data set going into a lot of extents was the impact this could have on prefetch read performance. Such a negative extent effect could in fact occur because - again, way back when - Db2 prefetch read operations were satisfied from spinning disk. Disk controller cache memory sizes were so small back in the day that Db2 would bypass cache for prefetch reads, and those multi-page reads from spinning disk could suffer, performance-wise, if the data set holding the page set or partition being accessed (table space or index) had gone into a good number of extents.

Things are different now, in a number of ways:

  • Db2 subsystem buffer pool configurations are MUCH larger than they were some years ago, owing largely to 1) mainframe memory getting less expensive all the time (on a per-gigabyte basis), leading organizations to load up on z/OS real storage (often to the tune of several hundred GB for a production z/OS LPAR); and 2) people realizing that if you give Db2 a lot of memory (e.g., for larger buffer pools), it generally performs really well. Much larger buffer pool configurations mean that a much higher percentage of Db2 page requests (synchronous and asynchronous) are satisfied from pages in memory, as opposed to requiring disk subsystem read I/O operations. Obviously, when page requests are satisfied from pages in memory, data set extents on disk are irrelevant.
  • Disk controller cache memory sizes have been really big for a long time; and, that large disk controller cache memory resource is managed in a high-performing way by powerful microprocessors that are an integral part of modern enterprise disk subsystems. What these large and intelligently managed disk controller cache resources mean is that a read request (synchronous or asynchronous) that cannot be satisfied from the buffer pool configuration will often result in a read from disk controller cache, as opposed to requiring a read from spinning disk. As is true for a read request that is satisfied from data in memory (in a buffer pool), data set extents are not relevant for a read of data from disk controller cache.
  • Even when a Db2 read request leads to accessing data all the way back on spinning disk, the architecture of modern enterprise disk subsystems - primarily RAID in nature - reduces the performance impact of data set extents from what it once was.
So, that's point #1: Db2 for z/OS data set extents just don't matter, from a performance perspective, as they once did. This point is underscored by the way in which Db2-managed secondary space allocation (the use of which I recommend) works. How do you get Db2 to manage secondary space allocation for data sets? You can do that by NOT including a SECQTY specification in a CREATE TABLESPACE or CREATE INDEX statement. For an existing table space or index, you can alter the object with a specification of SECQTY -1 to tell Db2 that you want it to manage secondary disk space allocation for the object. When Db2 manages secondary space allocation for a table space or index data set, it does so using what's called a "sliding scale" algorithm, which causes subsequent secondary space allocation quantities to be larger than those previously requested for the data set. If you check out the description of the sliding scale algorithm in the Db2 for z/OS documentation, you'll see the following (underlining added by me for emphasis): "The first 127 extents are allocated in increasing size, and the remaining extents..." Question for you: if extents were problematic from a performance perspective, would Db2's own secondary space allocation algorithm take you to 127 extents and beyond, as needed? Answer: NO. If Db2 doesn't care about this, should you? Again, NO.

"But wait," you might say, "Even if data set extents aren't a performance concern in a Db2 environment, there's a z/OS data set extent limit, right? If we hit that and Db2 can't extend a data set, application processes inserting rows into a table could fail, right?" True, but the data set extent limit is a lot bigger than it used to be. Back in the day, it was 251, and indeed that number might have me glancing in the rearview mirror with some of that "objects are closer than they may appear" anxiety. But quite some time ago - with z/OS 1.7 - the extent limit for a data set went to 7257 (when the Extent Constraint Removal option is set to YES in the SMS data class to which the data set belongs). When you let Db2 manage secondary space allocation for a table space or index data set, you are virtually assured that the data set will be able to reach its maximum size before it hits the extent limit.

Oh, and here's a fun fact: there is an EXTENTS column in the SYSIBM.SYSTABLESPACE and SYSIBM.SYSINDEXSPACE real-time statistics tables in the Db2 catalog. That column long had the SMALLINT data type, which can accommodate values of up to 32,767. When the Db2 catalog goes to the V13R1M501 level, the data type of the EXTENTS column changes to INTEGER - a type that can accommodate values of up to about 2.1 billion. I'd say this reflects an expectation that the z/OS data set limit is not going to stay at 7257 for the long haul.

So, would I ever be concerned with the number of extents to which a Db2 for z/OS table space or index data set has gone? I'd say that an extent value that's below 200 for a data set would not concern me. Above 200? Maybe, though not in a "front-burner" kind of way. If I saw that a Db2 data set had reached a number of extents greater than 200, I might be inclined to reduce that number at least somewhat, probably by going to a larger PRIQTY value for the object and executing an online REORG to put the change into effect. Again, though, this would not be a "crisis response" action - more like a Db2 housekeeping task.

Bottom line: if you've been spending your time and mainframe CPU time in being aggressive in keeping extent values low for Db2 data sets, my recommendation would be to ease up on that, because you can. Spend your time (and your mainframe's cycles) on more valuable tasks, like helping to get Db2-based applications designed (or enhanced) and deployed. That's where you'll make a bigger and more positive difference for your organization.