Author Archives: Administrator

Cluster mode to 7 mode

Maybe this will help.

The Controller is now set to boot c-mode. You need to change this at the LOADER prompt.

Procedure:

– halt controller

– at the boot loader, set the environment variable bootarg.init.boot_clustered to false

LOADER> setenv bootarg.init.boot_clustered false

– Install 7-mode

– boot into the boot menu and select 4 for the initial installation

How to move an aggregate between software disk-owned HA pairs.

How to move an aggregate between software disk-owned HA pairs.

 

KB ID: 1011651 Version: 7.0 Published date: 08/07/2014 Views: 3206

Description

This article explains, how move an aggregate from one controller in a HA pair to its partner in a software disk owned system. This procedure only applies to 7-mode systems.

Procedure

For reference: FILER1 owns the disk initially. FILER2 is where the disks/volume are being moved to.

WARNING:
Before starting this procedure, confirm that there are no aggregates or FlexVols on FILER2 that have the same name as the original aggregate/FlexVols or traditional volume being moved. Failure to do so will result in the relocated volume(s) with conflicting names being appended with a (1) instead of the original name.

Note:
This procedure is only supported under the following conditions:

  • Disks do not get moved, ownership remains of either node in HA pair.
  • If disks are moved outside the HA pair, shelf MUST NOT be moved.

It could be misunderstood to move disk/shelf to another filer using similar procedure. If the shelf needs to be moved outside of the HA pair, downtime is required.

    1. Start by taking the aggregate offline from FILER1.

Example:
For a traditional volume:

FILER1>aggr offline <volname>

      For an aggregate with FlexVols:

FILER1>priv set diag
FILER1*>aggr offline <volname> -a
FILER1*>priv set admin
FILER1>

    1. Move disk ownership of all disks in the aggr to FILER2.

WARNING:
The node on which the disk assign is done must be the node that is giving away the aggregate.

   FILER1> disk assign 0a.16 0a.17 0a.18 0a.19 -o FILER2 -f

(-f must be used since the disks are already owned)

    1. Verify that no further disks belonging to the original aggregate are left on the original node.

FILER1>aggr status -r <original-volname>

    1. Online the relocated aggregate from FILER2:

FILER2> aggr online <test>

Note:
It will be necessary to reconfigure any Common Internet File System Protocol (CIFS) shares,Network File System (NFS) exports or configure the appropriate igroups on the partner for the relocated volume(s) before clients can access this data.

Related Link:

 

Disclaimer

NetApp provides no representations or warranties regarding the accuracy, reliability, or serviceability of any information or recommendations provided in this publication, or with respect to any results that may be obtained by the use of the information or observance of any recommendations provided herein. The information in this document is distributed AS IS, and the use of this information or the implementation of any recommendations or techniques herein is a customer’s responsibility and depends on the customer’s ability to evaluate and integrate them into the customer’s operational environment. This document and the information contained herein may be used solely in connection with the NetApp products discussed in this document.

Configuring CNA ports and FC ports

Configuring CNA ports

If a node has onboard CNA ports or a CNA card, you must check the configuration of the ports and possibly reconfigure them, depending on how you want to use the upgraded system.

Before you begin

You must have the correct SFP+ modules for the CNA ports.

About this task

CNA ports can be configured into native Fibre Channel (FC) mode or CNA mode. FC mode supports FC initiator and FC target; CNA mode allows concurrent NIC and FCoE traffic the same 10GbE SFP+ interface and supports FC target. Continue reading

NetApp – Fix the “Bad Label” issue

NetApp – Fix the “Bad Label” issue

Recently I came across with a Bad Label error during the change of failed disk. My company changed the support company for one of our systems and the new one sent disks to replace the failed ones from the system. Normally the DC tech make a swap and assign the disks to the system, but this time he called me with an issue (from /etc/messages):

Thu May 22 13:02:54 CEST [NETAPP: raid.config.disk.bad.label:error]: Disk 9.10 Shelf 6 Bay 9 [NETAPP X291_S15KXXX0F15 NA01] S/N [3QQ312Y2XXXPBW] has bad label.
Thu May 22 13:02:54 CEST [NETAPP: raid.config.disk.bad.label:error]: Disk 6.70 Shelf 4 Bay 7 [NETAPP X291_S15KXXX0F15 NA01] S/N [3QQ3097KXXX5VU] has bad label.

 

To fix the issue I did:

NETAPP> priv set advanced
Warning: These advanced commands are potentially dangerous; use
them only when directed to do so by NetApp
personnel.
NETAPP*> vol status -f

Broken disks

RAID Disk Device HA SHELF BAY CHAN Pool Type RPM Used (MB/blks) Phys (MB/blks)
--------- ------ ------------- ---- ---- ---- ----- -------------- --------------
bad label 6.70 0d 4 7 FC:A 1 FCAL 15000 418000/856064000 420156/860480768
bad label 9.10 0d 6 9 FC:A 1 FCAL 15000 418000/856064000 420156/860480768
NETAPP*> disk unfail -s 6.70
disk unfail: unfailing disk 6.70...
NETAPP*> Fri May 23 08:42:47 CEST [NETAPP: raid.disk.unfail.done:info]: Disk 6.70 Shelf 4 Bay 7 [NETAPP X291_S15XXX0F15 NA01] S/N [3QQ3097KXXX5VU] unfailed, and is now a spare

NETAPP*> disk unfail -s 9.10
disk unfail: unfailing disk 9.10...
NETAPP*> Fri May 23 08:43:04 CEST [NETAPP: raid.disk.unfail.done:info]: Disk 9.10 Shelf 6 Bay 9 [NETAPP X291_S15XXX0F15 NA01] S/N [3QQ312Y2XXXPBW] unfailed, and is now a spare

NETAPP*> vol status -f

Broken disks (empty)
NETAPP*> vol status -s

Pool1 spare disks

RAID Disk Device HA SHELF BAY CHAN Pool Type RPM Used (MB/blks) Phys (MB/blks)
--------- ------ ------------- ---- ---- ---- ----- -------------- --------------
Spare disks for block or zoned checksum traditional volumes or aggregates
spare 6.70 0d 4 7 FC:A 1 FCAL 15000 418000/856064000 420156/860480768 (not zeroed)
spare 9.10 0d 6 9 FC:A 1 FCAL 15000 418000/856064000 420156/860480768 (not zeroed)
NETAPP* > priv set
NETAPP> disk zero spares
NETAPP>

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    7. installasi Listrik Penerangan Dalam rumah
    8. Timer Listrik
    9. Arester
    10. ELCB
    11. Sensor Cahaya
    12. Contactor
    13. Teknik Pengukuran Arus, tegangan, Hambatan  dan Daya
    14. ATS (automatic Transfer Switch)
    15. Panel Star Delta
    16. Motor 1 phase dan 3 phase.
    17. Capasitor bank
    18. PLC / Program Logic Control (Basic Program)

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Resistor (2)

Resistor adalah komponen elektronika yang berfungsi untuk menghambat atau membatasi aliran listrik yang mengalir dalam suatu rangkain elektronika. Sebagaimana fungsi resistor yang sesuai namanya bersifat resistif dan termasuk salah satu komponen elektronika dalam kategori komponen pasif. Satuan atau nilai resistansi suatu resistor di sebut Ohm dan dilambangkan dengan simbol Omega (Ω). Sesuai hukum Ohm bahwa resistansi berbanding terbalik dengan jumlah arus yang mengalir melaluinya. Selain nilai resistansinya (Ohm) resistor juga memiliki nilai yang lain seperti nilai toleransi dan kapasitas daya yang mampu dilewatkannya. Semua nilai yang berkaitan dengan resistor tersebut penting untuk diketahui dalam perancangan suatu rangkaian elektronika oleh karena itu pabrikan resistor selalu mencantumkan dalam kemasan resistor tersebut.

Continue reading

Kapasitor

Kapasitor adalah komponen elektronika yang dapat menyimpan dan melepaskan muatan listrik dalam waktu tidak tertentu. Berbeda dengan batere atau akumulator, kapasitor menyimpan dan melepaskan muatan tanpa terjadi perubahan kimia dalam kapastor tersebut. Kapasitor dibangun dari 2 buah plat yang dipisahkan oleh bahan dielektrik. Bahan yang digunakan sebagai dielektrik dalam suatu kapasitor ada beberapa jenis diantaranya udara, keramik, kaca, milar, mika, kertas, tantalum dan elektrolit. Berdasarkan dielektrikumnya kapasitor dibagi menjadi beberapa jenis kapasitor, antara lain:

  • Kapasitor Kertas
  • Kapasitor Keramik
  • Kapasitor Milar
  • Kapasitor Mika
  • Kapasitor Film
  • Kapasitor Elektrolit
  • Kapasitor Tantalum

Continue reading

Resistor (1)

Resistor tetap (Fix Resistor) adalah resistor yang nilai hambatannya tidak dapat diatur (tetap), sedangkan resistor variabel adalah resistor yang nilai resistansinya dapat diatur.  Dari kedua jenis resistor ini memiliki beberapa varian lagi yang disesuaikan dengan tujuan atau fungsi penggunaannya.

Resistor Tetap (Fix Resistor)

Resistor Tetap,fix resistorResistor Tetap (Fix Resistor)

Continue reading

Handling Watchdog Resets

Back

Handling watchdog resets

KB ID: 3013539 Version: 8.0 Published date: 01/15/2015 Views: 8592

 

Answer

  1. What is a watchdog reset?

A watchdog is an independent timer that monitors the progress of the main controller running Data ONTAP. Its function is to serve as an automatic server restart in the event the system encounters an unrecoverable system error.

The watchdog implemented by NetApp uses a two-level timer with different actions associated with each level of time.

  • Level 1: Timeout: The storage appliance attempts to panic and dump the core in response to a non-maskable interrupt. Once a L1 watchdog is successfully issued, the system returns to service and a core file is written, allowing NetApp to determine the root cause of the hang. A L1 watchdog is issued if the timer is not reset within 1.5 seconds.
  • Level 2: Reset: The storage appliance resets through a hard reset signal sent from the timer. A L2 watchdog is issued if the watchdog timer is not reset within two seconds after the L1 watchdog.

It is not necessary to ‘recover’ from a watchdog timeout or watchdog reset, as both of these events are recovery mechanisms for other failures. The objective instead is to identify the failure(s) that caused the watchdog event.

  1. What is the appropriate response to a watchdog timeout (L1 Watchdog Event)?
    A watchdog timeout should be treated just like any other system panic. The associated backtrace and/or the core should be analyzed for the possible root cause(s). A giveback should be performed if necessary.
  2. What is the appropriate response to a watchdog reset (L2 Watchdog Event)?

If the storage appliance receives a single watchdog reset, in general, no action needs to be taken as the condition causing the watchdog reset most often is a transient issue and would have been cleared by the reset process. A giveback should be performed if necessary, and the appliance should be monitored for repeat occurrences.
If a storage appliance takes multiple watchdog resets, look for previously logged errors associated with the CPU, motherboard, memory or I/O cards.

  1. Data to be collected to help diagnose the cause of a watchdog reset:
  • AutoSupports
  • Console logs before, during, and after the watchdog event (if possible)
  • ssram log (/etc/log/ssram/ssram.log or /mroot/etc/log/ssram/ssram.log) – FAS62xx only
  • On systems with a service processor: – system sensors – events all – system log – sp status -d

Note: No hardware should be replaced unless the root cause is a hardware issue.

 

Disclaimer

NetApp provides no representations or warranties regarding the accuracy, reliability, or serviceability of any information or recommendations provided in this publication, or with respect to any results that may be obtained by the use of the information or observance of any recommendations provided herein. The information in this document is distributed AS IS, and the use of this information or the implementation of any recommendations or techniques herein is a customer’s responsibility and depends on the customer’s ability to evaluate and integrate them into the customer’s operational environment. This document and the information contained herein may be used solely in connection with the NetApp products discussed in this document.