This document covers the following topics:
The Natural buffer pool is used to share Natural objects between several Natural processes that access objects on the same computer. It is a storage area into which compiled Natural programs are placed in preparation for their execution. Programs are moved into and out of the buffer pool as Natural users request Natural objects.
Since Natural generates reentrant Natural object code, it is possible that a single copy of a Natural program can be executed by more than one user at the same time. For this purpose, each object is loaded only once from the system file into the Natural buffer pool, instead of being loaded by every caller of the object.
The following topics are covered below:
Objects in the buffer pool can be any executable objects such as programs and maps. The following executable objects are only placed in the buffer pool for compilation purposes: local data areas, parameter data areas and copycodes.
When a Natural object is loaded into the buffer pool, a control block called a directory entry is allocated for that object. This control block contains information such as the name of the object, to which library or application the object belongs, from which database ID and Natural system file number the object was retrieved, and certain statistical information (for example, the number of users who are concurrently executing a program).
Resource sharing requires that access to the buffer pool be coordinated among all users. Several system resources are necessary to accomplish this. For example, shared memory on the Linux operating system is used to store the objects and their administrative information. To synchronize access to these objects, a set of semaphores is used. The amount of available shared memory and the number of semaphores is configured statically in the operating system, and as a result, it may be necessary to change system parameters and to recreate the operating system kernel for your installation. Further information about these topics is system-dependent and is described in the installation documentation for your Linux computer.
Depending on the individual requirements, it is possible to run different buffer pools of the same Natural version simultaneously on the same computer.
When a user executes a program, a call is made to the buffer pool manager. The directory entries are searched to determine whether the program has already been loaded into the buffer pool. If it does not yet exist in the buffer pool, a copy is retrieved from the appropriate library and loaded into the buffer pool.
When a Natural object is being loaded into the buffer pool, a new directory entry is defined to identify this program, and one or more other Natural objects which are currently not being executed may be deleted from the buffer pool to make room for the newly loaded object.
For this purpose, the buffer pool maintains a record of which user is currently using which object, and it detects situations in which a user exits Natural without releasing all its objects. It dynamically deletes unused or out-of-date objects to accommodate new objects belonging to other applications.
When a Natural object is executed, the Natural runtime system remembers the object name, the library (name, database ID and file number) and the address of the corresponding buffer pool directory entry. This data is referred to as "fast locate information".
When a Natural object is executed again, the Natural runtime system passes the fast locate information to the buffer pool manager and performs a time-saving fast locate call. A fast locate call bypasses the normal locate procedure including the steplib search and the search in the buffer pool. It is therefore the most efficient way to locate an object. It provides significantly better performance of subsequent program loads especially when steplib libraries are involved in multi-user environments.
The address of an object saved as fast locate information is no longer valid once the object is removed from the buffer pool, overwritten by another object or reloaded to another buffer pool location. If the fast locate call does not find the object at the given address, the object is searched in the buffer pool. If not found in the buffer pool, the object is reloaded from the system file.
This section covers the following topics:
Fast locate calls are issued when an object is accessed or
resumed. An object resume operation is performed, for example, when an object
continues to execute after a CALLNAT
statement. For object resume
operations, the Natural runtime system keeps fast locate information of the
calling object for each program level on the internal stack.
The Natural runtime system keeps fast locate information about each accessed object in the internal fast locate table. The fast locate table also contains information about all libraries in which an object was searched. For a subsequent call, a fast locate is issued if the current library and associated steplibs are still the same.
The fast locate table is a hash table. The entries can be directly accessed without searching for an object name. The hash value is calculated from the object name. It determines the slot index number for the object. If another object has the same hash value (hash collision), a normal locate call is performed and the entry in the fast locate table is overwritten.
If an object for the library given in the fast locate table is neither found in the buffer pool nor in the system file (which means that the object has been deleted or moved to another library), a normal locate call with the full steplib search is scheduled automatically.
The Locate Statistics of the buffer pool monitor shows how many locate attempts were made and how many of these attempts were fast locate calls (see Statistical Information About the Buffer Pool). These values can be used to review the efficiency of the fast locate table. If the fast locate table is activated for an application that calls the same objects many times, and if these objects are contained in a steplib library, the following applies:
The number of locate attempts should decrease significantly (compared with a deactivated fast locate table).
The number of fast locate attempts should be close to the number of locate attempts.
If the BPSFI
(Object Search
First in Buffer Pool) profile parameter is set to ON
, the fast
locate table is activated by default. It is initialized at the start of the
Natural session and it is not cleared implicitly during the running session. It
can be deactivated or cleared with the application programming interface
USR3004N as described in the section
Maintaining the Fast
Locate Table.
In the following example, a subprogram is called 3,000,000 times. In the first test, the subprogram is found in the current library, then in Steplib 1, Steplib 2, and so on. The red line shows the elapsed time needed for the program load with a deactivated fast locate table, the green line with an activated fast locate table.
The diagram above shows that there is no performance improvement if the object is found in the current library. The more steplibs there are involved in object search operations, the higher is the performance improvement. For five steplibs, the program loads require less than half the time.
If the BPSFI
profile
parameter is set to OFF
, the fast locate table is deactivated by
default. It can be activated or cleared with the application programming
interface USR3004N as described in the section
Maintaining the Fast
Locate Table. It is initialized at the start of the
Natural session and it is implicitly cleared when the application is back on
Program Level 0 (NEXT
prompt).
Activation of the fast locate table for BPSFI=OFF
can lead to unexpected results in the following scenario:
The list of steplibs contains the libraries S1 and S2 whereby S1 is searched before S2.
An object from S2 is accessed during the current Natural session.
Another Natural session copies a new version of this object into S1.
If the application is still running (not back on Program Level 0 in between) and the object is accessed again, the new version of the object will not be used.
If you want to activate the fast locate table when
BPSFI=OFF
is set, make sure that the scenario described above
cannot occur.
If BPSFI=ON
is set, object names should always be
unique across all libraries involved in object search operations. This also
guarantees that such scenarios do not occur.
In the following example, a subprogram is called 3,000,000 times. In the first test, the subprogram is found in the current library, then in Steplib 1, Steplib 2, and so on. The red line shows the elapsed time needed for the program load with a deactivated fast locate table, the green line with an activated fast locate table.
The diagram above shows that there is no performance
improvement if the object is found in the current library. The more steplibs
there are involved in object search operations, the higher is the performance
improvement. Since the search operation on the system file is considerably
slower than the search in the buffer pool, the improvement is much higher than
the corresponding improvement when BPSFI=ON
set. For five
steplibs, the program load is about 20 times faster. If the fast locate table
is activated, in general, the time needed for subsequent program loads for
BPSFI=OFF
is about the same as for BPSFI=ON
, and it
is always about the time needed to search for an object in the current library
only.
If an object is searched in a (read/write) buffer pool or on the system file, lock operations are issued to ensure that no other session performs changes concurrently. The lock operations serialize the access to the buffer pool, one session is processed after the other.
The fast locate table reduces the number of locate calls if steplibs are involved. Therefore, less lock operations are required, and overall performance of the buffer pool is improved.
In the following example, a subprogram is called 3,000,000 times, and the subprogram is always found in Steplib 5. In the first test, only one session is active. In the second test, two sessions execute the same application simultaneously, then three sessions, and so on. The red line shows the elapsed time needed for the program load with a deactivated fast locate table, the green line with an activated fast locate table.
As indicated in Performance with
BPSFI=ON, the program load with a single session is more
than 2 times faster if the object is found in Steplib 5 with
BPSFI=ON
set. If multiple sessions access the buffer pool
simultaneously, the tests show that the performance can be 3 to 5 times
faster.
Usage of the fast locate table can be activated and deactivated by calling the application programming interface (API) USR3004N. The API can also be used to get the current state of the fast locate table, to clear the fast locate table and to receive statistical data. The API is delivered in the SYSEXT library. For more information on using APIs, see the section SYSEXT Utility - Natural Application Programming Interfaces in the Utilities documentation.
To use API USR3004N
Copy the USR3004N subprogram to the SYSTEM library, to the appropriate steplib library, or to the required library.
The function to be performed by USR3004N requires that
the respective parameter value (ON
, OFF
,
STATE
, CLEAR
or COUNT
) is specified
first in the CALLNAT
statement. The parameter values can be
specified in uppercase or lowercase. On return, P-RETURN
contains
the return code, whereby Return Code 0 indicates that the function performed
successfully. All parameters are optional for compatibility with previous
versions of the API on the mainframe.
To activate the fast locate table
Call USR3004N with the following CALLNAT
statement:
CALLNAT 'USR3004N' 'ON' P-STATE 2X P-RETURN-CODE
To deactivate the fast locate table
Call USR3004N with the following CALLNAT
statement:
CALLNAT 'USR3004N' 'OFF' P-STATE 2X P-RETURN-CODE
To retrieve the current state of fast locate table usage
Call USR3004N with the following CALLNAT
statement:
CALLNAT 'USR3004N' 'STATE' P-STATE 2X P-RETURN-CODE
If the P-STATE
state field is
TRUE
, the fast locate table is used. The state field is returned
for each API function.
To clear the fast locate table
Call USR3004N with the following CALLNAT
statement:
CALLNAT 'USR3004N' 'CLEAR' P-STATE 2X P-RETURN-CODE
As described in
Fast Locate Table with
BPSFI=OFF, unexpected results can be encountered if the
fast locate table is used with BPSFI=OFF
. For
BPSFI=OFF
, the fast locate table is cleared when the application
is back on Program Level 0 (NEXT
prompt). A restart of the
application therefore ensures that the latest version of the object is found.
Since a server in a client/server environment never
reaches Program Level 0, you can clear the fast locate table by using the
CLEAR
function of USR3004N to ensure that the latest version of
the object is found.
To receive slot counts of the fast locate table
Call USR3004N with the following CALLNAT
statement:
CALLNAT 'USR3004N' 'COUNT' P-STATE P-SLOTS-USED P-SLOTS-TOTAL P-RETURN-CODE
The counters indicate how well the hash function operates. The hash function is used to calculate the slot index number in the fast locate table.
Field | Description |
---|---|
P-SLOTS-USED |
Shows the number of slots in
the fast locate table that are currently occupied.
The hash function operates well if this number increases with the number of objects accessed until close to the total number of slots. |
P-SLOTS-TOTAL |
Shows the total number of
slots available in the fast locate table.
The used hash function requires that the total number is a prime number. There are 593 slots available in the fast locate table. |
A read-only buffer pool is a special buffer pool that only allows read access. If an object is not found in the read-only buffer pool, Natural issues error 82 (object not found). As no attempt is made to retrieve the missing object in the system files, all lock operations on the system file as well as on the buffer pool are skipped. Account data are gathered.
A read-only buffer pool is defined in the Configuration Utility (see also Setting up a Buffer Pool below).
The utility NATBPSRV
expects a preload
list in a file named <bufferpool-name>.PRL at the
location of the Natural parameter files, which is defined in the local
configuration file (installation
assignments). For example, if the name of the read-only buffer pool
is "ROBP", the file name must be
ROBP.PRL.
A preload list can be generated using the Natural utility
CRTPRL
. This
utility extracts the contents of a buffer pool and merges it with the existing
preload data of a buffer pool.
The preload list in the PRL file contains records with comma-separated data in the following form:
database-ID,file-number,library,object-name,kind,type
The keywords in the file have the same meaning as the keywords
shown by the DIR
command of the NATBPMON
utility.
With the exception of directory-describing records (the kind of
object is D
, which means the object is part of
FILEDIR.SAG), a value must be assigned to all keywords.
Examples:
Keywords | NATBPSRV loads the
following into the buffer pool
|
---|---|
222,111,MY_LIB,PGM1,G,P |
Object code of program
PGM1 from library MY_LIB which is located on database
222 and file number 111.
|
222,113,*,*,D |
LIBDIR.SAG
which is located on FNAT=222,113 .
|
222,111,MY_LIB,*,D |
FILEDIR.SAG from
library MY_LIB which is located on FUSER=222,111 .
|
Using a read-only buffer pool has the disadvantage that the application must be known in detail (as missing objects cannot be loaded). This means that all objects needed by an application must be specified in the preload list. In seldom cases, the complete set of objects needed by an application can be determined in advance.
Natural can run with a read-only buffer pool as the primary
buffer pool. Such a buffer pool is not modifiable. Objects missing in the
read-only buffer pool cannot be loaded. If an object is not found in the
read-only buffer pool, Natural issues error 82 (object not found). To avoid
this, Natural can attach during execution to a secondary standard buffer pool
(which allows read/write access) and activate the missing objects there. If a
call to locate an object in the primary buffer pool fails, the secondary buffer
pool operates as a backup buffer pool. The dynamic parameter
BPID2
identifies the secondary buffer pool.
Other than for the read-only buffer pool, object locking through semaphores takes place each time the secondary buffer pool is accessed.
The preload list of the read-only buffer pool can be
updated/enhanced by merging the contents of the secondary read/write buffer
pool with the preload list of a read-only buffer pool using the utility
CRTPRL
.
For a read-only buffer pool, it is possible to define the name of an alternate buffer pool in the Configuration Utility (see also Setting up a Buffer Pool below).
Using the SWAP
command
of the NATBPMON
utility, which is only available for a read-only
buffer pool, you can tag a read-only buffer pool as "obsolete".
All Natural sessions attached to an obsolete buffer pool will detach from this
buffer pool and will attach to the alternate buffer pool - but only if the
alternate buffer pool is also a read-only buffer pool. The swap from one buffer
pool to the other occurs either when Natural tries to load a new object (for
example, when executing a CALLNAT
or RETURN
statement) or when Natural tries to interpret a command which has been put on
the stack. The IPC resources (that is, the shared memory segment) of a buffer
pool tagged as obsolete can be removed after issuing the
SWAP
command of the NATBPMON
utility.
This feature allows exchanging a buffer and its contents by another read-only
buffer pool with updated contents without stopping Natural sessions.
Known issues: The IPCRM
command of the
NATBPMON
utility will report an error trying to delete the
semaphores associated to a read-only buffer pool.
The Natural utility CRTPRL
, which is located in
the library SYSBPM
, is used to create a preload list for a
read-only buffer pool.
The utility uses the content of a source buffer pool as the basis for the preload list and checks whether the preload list already exists for a read-only (target) buffer pool:
If the preload list exists, the existing data in the preload list is merged with the data from the source buffer pool, and the preload list is saved with the new content.
If the preload list does not yet exist, it is created using the content from the source buffer pool.
The content of the resulting preload list determines the
content of the read-only buffer pool. The preload list is read by the utility
NATBPSRV
which
loads the corresponding objects into the read-only buffer pool.
When using the Natural buffer pool, only minimum restrictions must be considered:
When a Natural session hangs up, do not terminate it by
using the Linux
command kill -KILL
(also kill
-9
), the terminal command break
or the
interrupt key.
If this session is currently performing changes to the buffer pool internal data structures, an interruption may occur at a stage where the update is not fully completed. If the buffer pool internal data structures are inconsistent, this could have negative effects.
Instead, use the Linux command kill
-TERM
(also kill -15
) to terminate the
hung-up session.
Note:
This can only happen when the Natural nucleus is
executing buffer pool routines.
All resources must be shared among all users of one Natural buffer pool. Group membership of a process is used to give access rights for the buffer pool. This means that the shared memory can be changed by all group members, but not by anyone else. The same applies to the semaphores.
Note:
All users of the same Natural buffer pool must
belong to the same user group on the Linux operating system.
The buffer pool assignments are stored in the local configuration file. To set up a buffer pool, you have to specify specific values in the local configuration file using the Configuration Utility. For a list of these values, see Buffer Pool Assignments in the Configuration Utility documentation.
The buffer pool is created using the utility
NATBPSRV
.
Note:
The utility NATBPSRV
should not be accessible to
all Natural users, because it can cause damage to the work of other buffer pool
users.
NATBPSRV
allocates the resources required by the
buffer pool and creates the permanent communication facilities (that is, shared
memory and semaphores) used for the buffer pool. The necessary specifications
for the resources and facilities are made with the Configuration Utility (see
Setting up a Buffer
Pool).
The NATBPSRV
utility should only be used
during system startup, from within the startup procedure natstart.bsh.
By default, the buffer pool NATBP
is started. If another buffer pool is
to be started, you specify its name with the following NATBPSRV
command line option:
NATBPSRV BP = buffer-pool-name
If NATBPSRV
discovers in the process of
creating a buffer pool that a buffer pool of the same name is already active,
it deletes the already active buffer pool. If the deletion fails,
NATBPSRV
terminates with an appropriate error message.
NATBPSRV
can issue the following error messages if
the buffer pool that is to be created is meant to be a read-only buffer pool:
Unable to attach to buffer pool. Return code ... received from bp_init. | |
Explanation |
To load the objects described in the preload list,
|
Action |
Contact Software AG Technical Support. |
Unable to get parameter path. | |
Explanation |
The path defined in the local configuration file identifying Natural's parameter files could not be established. |
Action |
Contact Software AG Technical Support. |
File ... is not accessible. | |
Explanation |
The preload list is not accessible or not present. |
Action |
Revise access rights or create a preload list. |
Unable to open file ... | |
Explanation |
The preload list cannot be read. |
Action |
Re-create preload list. |
Skipped erroneous record: '...'. Buffer pool may not operate correctly. | |
Explanation |
An invalid record was found in the preload list. The record is skipped and the load process is continued. There may arise errors in your application due to missing objects. |
Action |
Correct the record if it has been created manually, or contact Software AG Technical Support. |
Unable to retrieve LIBDIR.SAG in FNAT(...,...). Application will not run. | |
Explanation |
LIBDIR.SAG was not found. An application
depending on |
Action |
Correct the record if it has been created manually, or contact Software AG Technical Support. |
Buffer pool manager returned with error code ... . Buffer pool is not operational. | |
Explanation |
FILEDIR.SAG could not be loaded into the buffer pool. The buffer pool is either too small to hold FILEDIR.SAG or FILEDIR.SAG is damaged. The previously listed message tells which FILEDIR.SAG is causing the trouble. |
Action |
Correct the record if it has been created manually, or contact Software AG Technical Support. |
Buffer pool manager returned with error code ... . Error ... occurred. | |
Explanation |
An error occurred loading an object into the buffer pool. |
Action |
Normally, the size of the buffer pool is too small. Increase its size and repeat the operation. If the problem remains, contact Software AG Technical Support. |
Object ... in library ... on system file (...,...) not found. Application may not run. | |
Explanation |
The preload record processed pointed to an object that was not found. This normally happens if an application is modified and the corresponding preload list is not updated. |
Action |
Remove/revise preload record in question |
Preload executed. Buffer pool is ready to run. | |
Explanation |
All preload records were processed. The buffer pool is unlocked and Natural can access that buffer pool. |
The Buffer Pool Monitor is used to oversee the buffer pool's activity during its operation. The Buffer Pool Monitor can also be used to shut down the buffer pool when Natural must be stopped on a computer.
The Buffer Pool Monitor collects information on the current state of your Natural buffer pool.
If multiple buffer pools are active on the same computer and an object that is loaded to more than one buffer pool is modified by a Natural process, the object will only be removed from the buffer pool to which the modifying Natural process is attached.
For detailed information for how to use the Buffer Pool Monitor, see
Using the Buffer Pool Monitor
(NATBPMON
).
This section describes problems that may occur when using the Natural buffer pool and how to solve them.
It is assumed that you are familiar with the Linux
commands ipcs
and adb
.
The following are typical command output examples, with an explanation of what went wrong during execution.
Either Natural or the Natural Buffer Pool Monitor (NATBPMON
utility) cannot be
started.
The following examples describe the most typical problems you are likely to encounter as a Natural administrator or user. These problems occur when you start Natural or the Natural Buffer Pool Monitor, and the buffer pool is not active.
You try to start Natural with the following command:
natural bp = sag
The following message appears:
Natural Startup Error: 16 Unable to open Buffer Pool, Buffer Pool error: "unexpected system call error occurred " (20) Global shared memory could not be attached.: shmkey = 11111111 Operating System Error 2 - No such file or directory
You try to start the Natural Buffer Pool Monitor with the following command:
natbpmon bp = sag
When you enter the WHO
command at
the NATBPMON
prompt, the following message appears:
Buffer Pool error: unexpected system call error occurred (20) Global shared memory could not be attached.: shmkey = 11111111 Operating System Error 2 - No such file or directory
Start the buffer pool service as described in Using the Utility NATBPSRV for Creating the Buffer Pool.
Use the Linux command ipcs
to
verify the existence of the necessary semaphores and the shared memory:
ipcs -m -s
This results in the following output:
IPC status from /dev/kmem as of Mon 23-MAY-2005 12:03:24.30 T ID KEY MODE OWNER GROUP Shared Memory: m 807 0x4e425031 --rw-rw---- sag natural Semaphores: s 85 0x4e425031 --ra-ra---- sag natural
Note:
The above output was edited to exclude memory segments
and semaphores that do not belong to the Natural buffer pool.
If you cannot find a shared memory segment or a set of semaphores with the key you assigned them, the buffer pool was not started.
The Natural buffer pool and a Natural utility are not of the same Natural version.
If a utility tries to use the buffer pool, the utility and buffer pool versions are checked for equality. If they differ, the access is denied and an error message is output.
You try to start Natural and the following message appears:
Natural Startup Error 16: Unable to open buffer pool. Buffer pool error: "Buffer pool does not correspond with your version of Natural"(25). Internal version of buffer pool is 0 but requested internal version is 1.
You try to start the Natural Buffer Pool Monitor and the following message appears:
Buffer pool error: Buffer pool does not correspond with your version of Natural (25). Internal version of buffer pool is 0 but requested internal version is 1.
Verify that your Natural version corresponds to your buffer pool version number and that the internal buffer pool version (BP version) is also correct. Restart the buffer pool with the same version as Natural but make sure that no other users are active.
Important:
The internal
buffer pool version number (BP version) can vary in between service
pack releases (third digit of the product version number). For example, a
buffer pool that has been initiated using Natural
Version
vrs cannot be used with Natural Version
vr(s+1) and vice versa.
Usually it should not be necessary to shut down and restart the buffer pool. This may only be necessary if the buffer pool should become unusable due to serious internal errors in the buffer pool, which is extremely unlikely to occur, or because the parameters defining the buffer pool structure became obsolete.
If the NATBPMON
utility is still able to access the buffer pool, proceed as
follows:
Shut down the buffer pool with the
SHUTDOWN
command of the NATBPMON
utility.
Once the SHUTDOWN
command is
executed, new users are denied access to the buffer pool.
Tip:
Active buffer pool users can be monitored by issuing the
WHO
and STATUS
commands
of the NATBPMON
utility.
After the last user has stopped accessing the buffer pool,
buffer pool resources can be deleted by issuing the
IPCRM
command of the NATBPMON
utility.
To restart the buffer pool, call the file natstart.bsh from a sufficiently privileged account.
If you have super user rights, you can use the FORCE
option of the
SHUTDOWN
command:
Shut down the buffer pool with the SHUTDOWN FORCE
grace-period
command of the
NATBPMON
utility.
This command - like the SHUTDOWN
command without options - denies new users access the buffer pool. However, the
terminate signal SIGTERM
is sent to all active Natural sessions,
forcing them to log off from the buffer pool.
If the optional parameter
grace-period is omitted, this command waits until
all active sessions have performed their shutdown processing and then executes
the IPCRM
command of the NATBPMON
utility .
If the optional parameter
grace-period has been specified,
NATBPMON
waits the specified number of seconds before it executes
its IPCRM
command - regardless of the closedown
status of the sessions logged on to the buffer pool. Therefore, the value
defined for the grace period should be sufficiently large to allow the sessions
to terminate in time.
Note:SHUTDOWN FORCE 0
is the same as
SHUTDOWN FORCE
(without the parameter
grace-period).
To restart the buffer pool after successful execution of the
SHUTDOWN FORCE
command, call the file
natstart.bsh from a
sufficiently privileged account.
If the NATBPMON
utility is not able to perform a
clean shutdown of the buffer pool, the buffer pool must be deleted by using
operating system commands:
Use the Linux command ipcs
to find
out the status of the buffer pool's shared memory and semaphores:
ipcs -a -m
In the column NATTCH of the output of an
ipcs -m -a
command, you can see the number of
processes currently attached to a shared memory segment. For example:
IPC status from /dev/kmem as of Mon May 23 12:15:38.39 2002 T ID KEY ... OWNER GROUP ... NATTCH SEGSZ Shared Memory: m 707 0x4e425031 ... sag natural ... 7 153600
It is highly probable that the number of processes attached to
shared memory incorporates a Natural nucleus or the NATBPMON
utility currently running. Inform the users who run these processes and ask
them to terminate their sessions or terminate them yourself by using the Linux
command kill
once you have found out their process
IDs using the ps
command.
Once you are sure that no one is using the buffer pool for
important work, its resources can be deleted by using the Linux command
ipcrm
. For example:
ipcrm -M 0x4e425031 -S 0x4e425031
The values specified for the -M
and
-S
options must be those that were specified inside the parameter
file used to start the buffer pool.
Be careful when you delete shared memory and semaphores using
the Linux command ipcrm
. If you accidentally delete
the wrong resource, this might have a serious impact on other software products
running on your computer.
The result of deletion can be verified by using the Linux
command ipcs
again.
If there are still some memory segments or message queues displayed, they could belong to other software, or they are marked for deletion because some other process is still attached to them.
If the buffer pool cannot be started after removing the shared memory and semaphores, you should consider either rebooting your computer or contacting Software AG Support.