Version 8.1.4
 —  DBA Tasks  —

Defining an Adabas Database

This document describes the procedure for defining an Adabas database. It is important for the DBA to understand the information provided for each step before attempting to define a new database.

Defining a new database involves the steps described in this document.

After you have completed these steps successfully, you can use the ADACMP and ADALOD utilities to load user files into the database.


Step 1 : Estimate the Size of the Database

This section covers the following topics:

Components Required by the Nucleus

The Adabas nucleus requires three database components: Data Storage, an Associator, and a Work area.

Data Storage

The Data Storage component contains the compressed data records of each file in the database.

Associator

The Associator contains elements for each file in the database and for the database as a whole.

For each file in the database, the Associator includes an inverted list, an address converter, and a field definition table (FDT):

For the database as a whole, the Associator includes storage management tables and coupling lists:

Work

The Work area stores information in four parts:

Other Components

Sort and Temp Areas

The Adabas utilities ADAINV, ADALOD, and ADAVAL require two additional data sets, SORT and TEMP, for sorting and intermediate storage of data.

The sizes of TEMP and SORT vary according to the utility function to be executed. These data sets can be allocated during the job and then released, or permanent data sets can be allocated and reused.

Logs

Adabas has the following optional logs:

Note:
Each CLOG, PLOG, and RLOG data set is limited to 16,777,215 (x'FFFFFF') blocks/RABNs.

General Space Requirements

The space requirements for the Associator (NI, UI, and AC) and Data Storage are calculated automatically for each file by the ADALOD utility and the ADACMP utility, respectively. If you want to allocate a specific amount of space to a file or estimate the space needed for a file without actually executing these utilities, you can use the formulas provided in this chapter.

If the number and size of the files that will eventually be loaded into the database are not known at the time that the database is established, it is not necessary to allocate a large amount of extra space to the Associator and/or Data Storage, since the space may be increased subsequently by using the ADD or INCREASE function of the ADADBS utility.

The initial allocation for Associator and Data Storage should, however, allow for the loading of all currently planned files in addition to a reasonable amount of database expansion (adding new files or updating existing files).

When estimating the Associator space, the following requirements for the database as a whole must be added to the estimates calculated for each file within the database (normal index, upper indexes, and address converter):

General Procedure for Estimating Space

  1. Estimate the following requirements for each file; then add the estimates together for an estimate for the whole database:

  2. Estimate the following requirements for the database as a whole:

Estimation Formulas

The following sections provide formulas for estimating the space that should be allocated to each component.

Rules of Precedence in the Formulas

The formulas follow the normal rules of precedence; that is, expressions are evaluated in the following order:

  1. Elements in parentheses;

  2. Multiplication and division operations;

  3. Addition and subtraction operations;

  4. Left to right (when elements have the same precedence level, the one on the left is evaluated first).

Normal Index (NI)

Use the following formula to estimate the normal index space required for each descriptor in the file:

NIRBYTES = ISNSIZE * AVUQVAL * RECORDS + DESCVALS * (AVLENG + 2)

where

NIRBYTES is the space requirement for normal index, in bytes.
ISNSIZE is the length of ISNs in the file (3 or 4 bytes). The ISN length is specified by the ADALOD parameter ISNSIZE.
AVUQVAL is the average number of unique values for the descriptor in each record.
RECORDS is the number of records to be contained in the file, which is specified by the ADALOD parameter MAXISN.
DESCVALS is the number of unique values for the descriptor in the file.
AVLENG is the average length of the values for the descriptor.

AVUQVAL

AVUQVAL is less than or equal to 1 unless the descriptor is a multiple-value field (MU) or part of a periodic group (PE).

If the descriptor is defined with the NU (null suppression) option, AVUQVAL equals the average number of values per record minus the percentage of records that contain a null value (the field is empty). For example, if each record has one value for the descriptor and 20 per cent of the values are null

AVUQVAL = 1 - 0.2 = 0.8

Similarly, if an MU field has an average of 10 values per record and 20% of the values are null

AVUQVAL = 10 - 2 = 8

AVLENG

If the descriptor field is not defined with the FI (fixed length) option, AVLENG equals the average compressed length of the field, including the length byte. If the descriptor is defined with the FI option, AVLENG equals the standard length of the field.

ISNSIZE * AVUQVAL * RECORDS

ISNSIZE * AVUQVAL * RECORDS represents the space required to store the ISNs. It is the important factor for descriptors that have many duplicate values.

DESCVALS * (AVLENG + 2)

DESCVALS * (AVLENG + 2) represents the space required to store the descriptor values. It is the important factor for descriptors that have a large proportion of unique values.

Convert Bytes to Blocks

Use the following formula to convert bytes to blocks. Round the result up to the next block.

 NIRBLOCKS = NIRBYTES / (ASSOBLKSIZE * (1 - PADFACTOR / 100))

where

NIRBLOCKS is the NI space requirement, in blocks.
NIRBYTES is the NI space requirement, in bytes (from the NIRBYTES formula).
ASSOBLKSIZE is the ASSOR1 block length. To review a list of block sizes by device type and component, refer to the sections entitled Device And File Considerations in the Adabas installation documentation for the appropriate system platform (z/OS, VSE, z/VM, or BS2000).
PADFACTOR is the ASSOR1 block padding factor, which is a percentage of the block length expressed as a value between 1-90.

Examples

The following examples assume that ASSOR1 is stored on a 3380 device.

Example 1:

Descriptor AA has one value per record and no null values. There are 50 different values for AA in the file. The average compressed length for the values is 3 bytes.

ISNSIZE=3
MAXISN=20000
PADFACTOR=10 (%)

NIRBYTES  = 3 * 1 * 20,000 + 50 * (3 + 2)
                     = 60,000 + 250
                     = 60,250 bytes
NIRBLOCKS  = 60,250 / (2004 * (1 - 0.1))
                        = 33.41
                        = 34 blocks

Example 2:

Descriptor BB has one value per record and no null values. There are 20,000 different values for BB in the file. The average compressed length for the values is 10 bytes.

ISNSIZE=4
MAXISN=20000
PADFACTOR=10 (%)

NIRBYTES  = 4 * 1 * 20,000 + 20,000 * (10 + 2)
                     = 80,000 + 240,000
                     = 320,000 bytes
NIRBLOCKS  = 320,000 / (2004 * (1 - 0.1))
                        = 177.42
                        = 178 blocks

Example 3:

Descriptor CC is a null-suppressed multiple-value (MU) field with an average of 10 occurrences and 3 null values per record. There are approximately 300 different values for CC in the file. The average compressed length for the values is 4 bytes.

ISNSIZE=3
MAXISN=10000
PADFACTOR=5 (%)

NIRBYTES  = 3 * 7 * 10,000 + 300 * (4 + 2)
                     = 210,000 + 1,800
                     = 211,800 bytes
NIRBLOCKS  = 211,800 / (2004 * (1 - 0.05))
                        = 111.25
                        = 112

Example 4:

Descriptor DD is a null-suppressed field contained within a periodic group. DD contains an average of 5 values per record; there is an average of 3 null values per record. There are 10 different values for DD in the file. The average compressed length for the values is 5 bytes.

ISNSIZE=4
MAXISN=10000
PADFACTOR=5 (%)

NIRBYTES  = 4 * 2 * 10,000 + 10 * (5 + 2)
                     = 80,000 + 70
                     = 80,070 bytes
NIRBLOCKS  = 80,070 / (2004 * (1 - 0.05))
                        = 42.06
                        = 43

Upper Index (UI)

Use the following formula to estimate the UI space required for each descriptor in the file:

UIRBYTES = NIRBLOCKS * (AVDESCLEN + ISNSIZE + RABNSIZE + 1)

where

UIRBYTES is the UI space requirement, in bytes.
NIRBLOCKS is the NI space requirement, in blocks (from the NIRBLOCKS formula).
AVDESCLEN is the average compressed length of the values for the descriptor.
ISNSIZE is the length of ISNs in the file (3 or 4 bytes). The ISN length is specified by the ADALOD parameter ISNSIZE.
RABNSIZE is the length of RABNs in the database (3 or 4 bytes). The RABNSIZE is specified for all files in a database when the database is defined.

Note:
RABNSIZE refers only to the length of the relative Adabas block number. It does not refer to the block size.

Convert Bytes to Blocks

Use the following formula to convert bytes to blocks. Round the result up to the next block.

UIRBLOCKS = UIRBYTES / (ASSOBLKSIZE * (1 - PADFACTOR / 100))

where

UIRBLOCKS is the UI space requirement, in blocks.
UIRBYTES is the UI space requirement, in bytes (from the UIRBYTES formula).
ASSOBLKSIZE is the ASSOR1 block length. To review a list of block sizes by device type and component, refer to the sections entitled Device And File Considerations in the Adabas installation documentation for the appropriate system platform (z/OS, VSE, z/VM, or BS2000).
PADFACTOR is the ASSOR1 block padding factor, which is a percentage of the block length expressed as a value between 1-90.

Example

This example assumes that the Associator is stored on a 3380 DASD; therefore, ASSOR1 has 2004 bytes per block.

The NI block requirement for this file is estimated to be 45 blocks. The average compressed length of the values for the descriptor is 3 bytes. The database has 3-byte (24-bit) RABNs; the file has 3-byte ISNs. The ASSOR1 block padding factor is 5 (%).

UIRBYTES  = 45 * (3 + 3 + 3 + 1)
                     = 450
UIRBLOCKS  = 450 / (2004 * (1 - 0.05))
                        = 450 / 1903.8
                        = 0.24
                        = 1 block( a minimum of 2 blocks can be allocated for the UI)

Address Converter (AC)

Use the following formula to estimate the address converter space required for the file. Round the result up to the next whole block.

ACBLOCKS = (MAXISN +!) * RABNSIZE / ASSOBLKSIZE

where

ACBLOCKS is the space requirement for the address converter, in blocks.
MAXISN is the MAXISN setting for the file.
RABNSIZE is the length of RABNs in the database (3 or 4 bytes). The RABNSIZE is specified for all files in a database when the database is defined.

Note:
RABNSIZE refers only to the length of the relative Adabas block number. It does not refer to the block size.

ASSOBLKSIZE is the Associator block size. To review a list of block sizes by device type and component, refer to the sections entitled Device And File Considerations in the Adabas installation documentation for the appropriate system platform (z/OS, VSE, z/VM, or BS2000).

Examples

The following examples assume that the Associator is stored on a 3380 DASD; ASSOR1 has 2004 bytes per block.

Example 1:

MAXISN=2000000
RABNSIZE=3

ACBLOCKS  = (2,000,000 * 3) / 2004
                     = 6,000,000 / 2004
                     = 2994.01
                     = 2995 blocks

Example 2:

MAXISN=2000000
RABNSIZE=4

ACBLOCKS  = (2,000,000 * 4) / 2004
                     = 8,000,000 / 2004
                     = 3992.02
                     = 3993 blocks

Data Storage

Use the following formula to estimate the space required for Data Storage. Round the result up to the next whole block.

DATASTORAGE = MAXISN / ((DSBLKSIZE * (1 - (PADFACTOR / 100))) / AVRECLEN)

where

DATASTORAGE is the space requirement for Data Storage, in blocks.
MAXISN is the MAXISN setting for the file.
DSBLKSIZE is the Data Storage block size, rounded down to the next integer. To review a list of block sizes by device type and component, refer to the sections entitled Device And File Considerations in the Adabas installation documentation for the appropriate system platform (z/OS, VSE, z/VM, or BS2000).
PADFACTOR is the Data Storage block padding factor, which is a percentage of the block length expressed as a value between 1-90.
AVRECLEN is the average compressed record length.

Example

MAXISN = 1000000
Average compressed record length = 50
Model 3380 block size for DATA = 4820
Data Storage block padding factor = 5 (%)

DATASTORAGE  = 1,000,000 / ((4820 * (1 - 0.05)) / 50)
                               = 1,000,000 / (4579 / 50)
                               = 1,000,000 / 91
                               = 10,989.01
                               =  10,990 blocks

How Adabas Allocates Work Space

When you allocate the Work data sets, allocate enough space for all parts. The minimum allowable Work space is 300 blocks. Three ADARUN parameters can be used to break up the space into parts 1-4 as follows:

Note:
Work part 4 or DDWORKR1 is no longer supported if you have Adabas Transaction Manager Version 7.5 or later installed. Instead, you should use the DDWORKR4 data set. DDWORKR4 is a container data set used for the same purpose as Work part 4, but it can be used in parallel by all members in a cluster. The DDWORKR4 data set should be allocated and formatted in the normal way, using a block size greater than or equal to DDWORKR1. It should be at least as large as the cluster’s LP parameter of the database or cluster.

Work part 2 begins in the block following the last block of Work part 1; thus, the first RABN of part 2 is given by

1 + LP

Work part 4 begins in the block following the last block of Work part 2; thus, the first RABN of part 4 is given by

1 + LP + LWKP2

Work Part 1: Data Protection Information

The data protection area for all transactions running in parallel must fit into 1/4 of the Work part 1 (that is, LP) area. Following are general guidelines for determining the proper size for Work part 1:

  1. The total Work part 1 size should be four times the estimated size required for a single average transaction in bytes times the maximum number of transactions that run in parallel. This value is then divided by the Work block size (in bytes) minus 200 to convert bytes to blocks.

  2. If some transactions are very long, then those transactions alone plus all short transactions executed in parallel should be used to determine the size of a single average transaction.

  3. The size of a single average transaction is determined by estimating the average number of updates (modifications, additions, and deletions) per transaction and multiplying that number by the estimated bytes required per update. To this is added space for ET data and for the ET record in bytes.

  4. The size required per update is determined by the average compressed record length in bytes times 4 (before image, after image, and DVT space for each) plus 100 bytes for each protection record header (that is, 100 times 4).

A formula that expresses these guidelines is

WK1= ( 4 * TASIZE * TAP ) / ( BLKSIZE - 200 )

where

WK1 is size of Work part 1 in blocks
TASIZE is the size of a single average transaction in bytes
TAP is the maximum number of transactions actually executed in parallel
BLKSIZE is the Work block size in bytes
TASIZE= ( ( ( 4 * AVCRL ) + 400 ) * UPDTA ) + ETDATA + 100

where

AVCRL is the average compressed record length in bytes
UPDTA is the average number of updates per transaction
ETDATA is the average length of ET data in bytes

Example

If AVCRL = 300 bytes, UPDTA = 4, and ETDATA = 200 bytes, then

TASIZE= ( ( ( 4 * 300 ) + 400 ) * 4 )+ 200 + 100 = 6700 bytes

If TAP = 100 and BLKSIZE = 5492, then

WK1 = ( 4 * 6700 * 100 ) / ( 5492 - 200 ) = 506.46 blocks

Work Part 2: Intermediate Search Results

Use the following formula to estimate the space required for the Work part 2 area. Round the result up to the next whole block.

WORK2 = 22 + 2 * ((4 * RECORDS) / (BLKSIZE - 16))

where

WORK2 is the Work part 2 space requirement, in blocks.
RECORDS
is the number of records in the file with the most records. This number equals
TOPISN - MINISN + 1
where:
TOPISN is the highest ISN currently used in the file.
MINISN is the lowest ISN used in the file.
The MINISN value is specified with the ADACMP/ADALOD parameter MINISN; 1 is the default. You can use the ADAREP utility to display the TOPISN and MINISN values for the files in a database.
BLKSIZE is the block size of the device where the Work data set is stored. To review a list of block sizes by device type and component, refer to the sections entitled Device And File Considerations in the Adabas installation documentation for the appropriate system platform (z/OS, VSE, z/VM, or BS2000).

Note:
An Adabas internal table requires one byte of storage for each Work part 2 block.

Example

The number of records in the largest file in the database is 500,000. The Work data set is stored on a 3380 device.

WORK2 = 22 + 2 * ((4 * 500,000) / (5492 - 16))
               = 752.46
               = 753 blocks

Work Part 3: ISN Lists from Search Commands

Adabas allocates to Work part 3 (resultant ISN lists) the Work space remaining after the allocation of the part 1 (data protection information) and part 2 (intermediate results) areas.

The minimum requirement for this area is 50 blocks.

If insufficient space is provided for this area, Adabas may be unable to execute additional search commands until the space currently occupied by ISN lists has been released. Consider the following factors when estimating the space needed for the Work part 3 area:

Example

A maximum of 100 search commands with an average of 25 resulting ISNs per command are to be processed concurrently during the session.

Adabas will need 100 blocks in the Work part 3 area.

Work Part 4: Data Related to Distributed Transaction Processing

Note:
Work part 4 of DDWORKR1 is no longer supported if you have Adabas Transaction Manager Version 7.5 or later installed. Instead, you should use the DDWORKR4 data set. DDWORKR4 is a container data set used for the same purpose as Work part 4, but it can be used in parallel by all members in a cluster. The DDWORKR4 data set should be allocated and formatted in the normal way, using a block size greater than or equal to DDWORKR1. It should be at least as large as the cluster’s LP parameter of the database or cluster.

Work part 4 maintains information about some of the global transactions involved in distributed processing. For example, during phase one of the commit process, a global transaction's protection data may be copied from Work part 1 to Work part 4 if it is no longer possible to store the information in Work part 1.

If an overflow of Work part 4 is pending, the nucleus can force a transaction termination. This clears Work part 4 except for transaction IDs (XIDs) and local transaction status information.

The required size of Work part 4 depends on the applications running against the database and on the system load. If you have Adabas Transaction Manager Version 7.4 or earlier installed, a safe size of LP/4 is a good value to start with. If you have Adabas Transaction Manager 7.5 or later installed, a minimum size of 8 blocks must be specified, with the maximum number of blocks being the size of the DDWORK4 data set divided by 8.

Because the information maintained in Work part 4 cannot currently be moved to a different area, you can alter the size of Work part 4 between sessions only as follows:

Sort

The following formulas estimate the sort data set space used for sorting all values of a single descriptor. Multiple descriptors are sorted successively: all values are sorted for the first descriptor, then all values for the second descriptor, and so on. Therefore, estimate the space for the largest possible descriptor sort; that will be enough for all descriptors.

Use the following formula to estimate the space required for the sort area:

DESCSPACE = (AVDESCLEN + (1 + ISNSIZE)) * NUMRECS * AVPEOCCUR * AVMVOCCUR

where

DESCSPACE is the total descriptor space required, in bytes.
AVDESCLEN is the average compressed descriptor length, in bytes.
ISNSIZE is the size of the ISN being used (either 3 or 4).
NUMRECS is the number of records.
AVPEOCCUR is the average number of periodic group occurrences, if the descriptor is in a periodic group. Otherwise, set this value to 1.
AVMVOCCUR is the average number of multiple-value field occurrences, if the descriptor is a multiple-value field. Otherwise, set this value to 1.

Work Pool Size

Use the following formula to estimate the space required for the work pool:

LWPAVAIL = LWPSIZE - 1216 - (32 * SORTDEVTRKS) - SORTDEVBSIZ

where

LWPAVAIL is the available part of the work pool space, in bytes.
LWPSIZE is the total work pool size, in bytes (the utility's LWP parameter value).
SORTDEVTRKS is the number of sort device tracks per cylinder. To review a list of block sizes by device type and component, refer to the sections entitled Device And File Considerations in the Adabas installation documentation for the appropriate system platform (z/OS, VSE, z/VM, or BS2000).
SORTDEVBSIZ is the sort device block size, in bytes.

Sorted Partial Sequences

To determine the space required for sorted partial sequences, use one of the following calculations. The one to use depends on the AVDESCLEN value (average descriptor length) used to calculate the DESCSPACE value (total descriptor space required).

LENGSEQ = (LWPAVAIL * (AVDESCLEN + (1 + ISNSIZE))) / 2

where

LENGSEQ is the length of sorted partial sequences.
LWPAVAIL is the available Work pool space.
AVDESCLEN is the average compressed descriptor length, in bytes.
ISNSIZE is the size of the ISN being used (either 3 or 4).
LENGSEQ = (LWPAVAIL * 2) / 3

where

LENGSEQ is the length of sorted partial sequences.
LWPAVAIL is the available Work pool space.

Device Surfaces

Use the following formula to calculate the number of device surfaces rounded up to the next integer:

SURFACES = (DESCSPACE / LENGSEQ) / SORTDEVTRK

where

SURFACES is the number of surfaces required for sort space, rounded up to the next integer.
DESCSPACE is the total descriptor space required, in bytes.
LENGSEQ is the length of sorted partial sequences.
SORTDEVTRKS is the number of sort device tracks per cylinder. To review a list of block sizes by device type and component, refer to the sections entitled Device And File Considerations in the Adabas installation documentation for the appropriate system platform (z/OS, VSE, z/VM, or BS2000).

Estimated Sort Size

Using the intermediate values calculated for LENGSEQ and SURFACES, compute the estimated sort size as follows:

SORTSIZE = (SURFACES * SORTDEVTRKS * LENGSEQ * 2) / (SORTDEVBSIZ - 4)

where

SORTSIZE is the estimated sort area size, in blocks. This value should be rounded up to the next full cylinder.
SURFACES is the number of surfaces required for sort space, calculated earlier and rounded up.
SORTDEVTRKS is the number of sort device tracks per cylinder. To review a list of block sizes by device type and component, refer to the sections entitled Device And File Considerations in the Adabas installation documentation for the appropriate system platform (z/OS, VSE, z/VM, or BS2000).
LENGSEQ is the length of sorted partial sequences.
SORTDEVBSIZ is the sort device block size, in bytes.

Number of Descriptors Sorted

Use the following formula to estimate the number of descriptors that can be sorted in the SORTSIZE space calculated in the previous formula (assuming the same descriptor definition that was used when calculating DESCSPACE):

DESCOUNT = SURFACES * SORTDEVTRKS * LENGSEQ / (AVDESCLEN + (1 + ISNSIZE))

where

DESCOUNT is the number of descriptors defined in the earlier DESCSPACE calculation that can be held in the SORTSIZE space calculated above.
SURFACES is the number of surfaces required for sort space, calculated earlier and rounded up.
SORTDEVTRKS is the number of sort device tracks per cylinder. To review a list of block sizes by device type and component, refer to the sections entitled Device And File Considerations in the Adabas installation documentation for the appropriate system platform (z/OS, VSE, z/VM, or BS2000).
LENGSEQ is the length of sorted partial sequences.
AVDESCLEN is the average compressed descriptor length, in bytes.
ISNSIZE is the size of the ISN being used (either 3 or 4).

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Step 2 : Allocate Space

  1. Use standard operating-system procedures to allocate data sets for the following Adabas components:

  2. To minimize contention and distribute I/O activity more evenly across hardware channels, place the ASSO, DATA, WORK, PLOG, and RLOG data sets on different physical volumes. If only two volumes are available, place ASSO on one volume and DATA and WORK data sets on the second.

    The WORK and PLOG data sets should be on different volumes, since a PLOG I/O operation is always followed by a WORK I/O operation.

    The RLOG data set should always be placed on a separate device of the same type.

    Disk access time may be considerably reduced by separating TEMP from DATA, and SORT from ASSO. When loading files containing 100,000 records or more, splitting SORT across two volumes reduces disk arm movement.

  3. Specify the disk space allocation in the job control (JCL/JCS or VM CONTROL minidisk) of the format utility (ADAFRM). See the Adabas Utilities documentation for specific information and job examples.

Examples

Example 1 : Database Allocation Using Two Volumes

Volume 1 Volume 2      
ASSO DATA      
TEMP WORK      
PLOG1 SORT      
PLOG2        

Example 2 : Database Allocation Using Three Volumes

Volume 1 Volume 2 Volume 3    
ASSO DATA WORK    
PLOG1 SORT TEMP    
  PLOG2      

Example 3 : Database Allocation When Loading a Large File

Volume 1 Volume 2 Volume 3 Volume 4 Volume 5
ASSO DATA DATA DATA SORT (2nd half)
  PLOG1 PLOG2 SORT (1st Half) WORK
    TEMP    

Performance Note

Software AG does not recommend using hardware compression (IDRC) for protection log files. The ADARES utility BACKOUT function will run at least twice as long under z/OS when processing compressed data. Also, the BACKOUT function is not supported for compressed data on VSE or z/VM systems.

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Step 3 : Format the Space

Before loading the first file into the database, use the ADAFRM utility to format the ASSO, DATA, and WORK data sets. Refer to the Adabas Utilities documentation for information about the ADAFRM utility.

Format TEMP and SORT before using any Adabas utility that requires them. You can allocate and format temporary data sets and delete them after executing the utility, or allocate and format permanent data sets for repeated use.

Note:
When using the Recovery Aid (including the RLOG), you must catalog all temporary data sets. When running with the Recovery Aid, the general rule is to catalog temporary data sets in jobs that require the Associator data sets.

Format the CLOG, PLOG, and RLOG data sets before starting the first session in which the logging is to be performed.

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Step 4 : Define Database Parameters

Once all database components have been physically allocated and formatted, use the ADADEF utility to define database parameters such as database identification, maximum number of files, system file assignment, and so on.

The sizes of the ASSO, DATA, and WORK data sets must be defined with ADADEF DEFINE parameters. Note that defining the sizes to Adabas is different from allocating the space; the data sets must be allocated and formatted before you can define them to Adabas. The sizes of the other data sets are defined to Adabas as follows:

Note:
Each log data set (CLOG, PLOG, or RLOG) is limited to 16,777,215 (x'FFFFFF') blocks/RABNs.

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