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InfoScale™ 9.0 Solutions Guide - Linux
Last Published:
2025-04-14
Product(s):
InfoScale & Storage Foundation (9.0)
Platform: Linux
- Section I. Introducing Veritas InfoScale
- Section II. Solutions for Veritas InfoScale products
- Solutions for Veritas InfoScale products
- Use cases for Veritas InfoScale products
- Feature support across Veritas InfoScale 9.0 products
- Using SmartMove and Thin Provisioning with Sybase databases
- Running multiple parallel applications within a single cluster using the application isolation feature
- Scaling FSS storage capacity with dedicated storage nodes using application isolation feature
- Finding Veritas InfoScale product use cases information
- Solutions for Veritas InfoScale products
- Section III. Stack-level migration to IPv6 or dual stack
- Section IV. Improving database performance
- Overview of database accelerators
- Improving database performance with Veritas Concurrent I/O
- Improving database performance with atomic write I/O
- About the atomic write I/O
- Requirements for atomic write I/O
- Restrictions on atomic write I/O functionality
- How the atomic write I/O feature of Storage Foundation helps MySQL databases
- VxVM and VxFS exported IOCTLs
- Configuring atomic write I/O support for MySQL on VxVM raw volumes
- Configuring atomic write I/O support for MySQL on VxFS file systems
- Dynamically growing the atomic write capable file system
- Disabling atomic write I/O support
- Section V. Using point-in-time copies
- Understanding point-in-time copy methods
- Backing up and recovering
- Storage Foundation and High Availability Solutions backup and recovery methods
- Preserving multiple point-in-time copies
- Online database backups
- Backing up on an off-host cluster file system
- Database recovery using Storage Checkpoints
- Backing up and recovering in a NetBackup environment
- Off-host processing
- Creating and refreshing test environments
- Creating point-in-time copies of files
- Section VI. Maximizing storage utilization
- Optimizing storage tiering with SmartTier
- About SmartTier
- About VxFS multi-volume file systems
- About VxVM volume sets
- About volume tags
- SmartTier use cases for Sybase
- Setting up a filesystem for storage tiering with SmartTier
- Relocating old archive logs to tier two storage using SmartTier
- Relocating inactive tablespaces or segments to tier two storage
- Relocating active indexes to premium storage
- Relocating all indexes to premium storage
- Optimizing storage with Flexible Storage Sharing
- Optimizing storage tiering with SmartTier
- Section VII. Migrating data
- Understanding data migration
- Offline migration from LVM to VxVM
- Offline conversion of native file system to VxFS
- Online migration of a native file system to the VxFS file system
- About online migration of a native file system to the VxFS file system
- Administrative interface for online migration of a native file system to the VxFS file system
- Migrating a native file system to the VxFS file system
- Migrating a source file system to the VxFS file system over NFS v4
- Backing out an online migration of a native file system to the VxFS file system
- VxFS features not available during online migration
- Migrating storage arrays
- Migrating data between platforms
- Overview of the Cross-Platform Data Sharing (CDS) feature
- CDS disk format and disk groups
- Setting up your system to use Cross-platform Data Sharing (CDS)
- Maintaining your system
- Disk tasks
- Disk group tasks
- Changing the alignment of a disk group during disk encapsulation
- Changing the alignment of a non-CDS disk group
- Splitting a CDS disk group
- Moving objects between CDS disk groups and non-CDS disk groups
- Moving objects between CDS disk groups
- Joining disk groups
- Changing the default CDS setting for disk group creation
- Creating non-CDS disk groups
- Upgrading an older version non-CDS disk group
- Replacing a disk in a CDS disk group
- Setting the maximum number of devices for CDS disk groups
- Changing the DRL map and log size
- Creating a volume with a DRL log
- Setting the DRL map length
- Displaying information
- Determining the setting of the CDS attribute on a disk group
- Displaying the maximum number of devices in a CDS disk group
- Displaying map length and map alignment of traditional DRL logs
- Displaying the disk group alignment
- Displaying the log map length and alignment
- Displaying offset and length information in units of 512 bytes
- Default activation mode of shared disk groups
- Additional considerations when importing CDS disk groups
- File system considerations
- Considerations about data in the file system
- File system migration
- Specifying the migration target
- Using the fscdsadm command
- Checking that the metadata limits are not exceeded
- Maintaining the list of target operating systems
- Enforcing the established CDS limits on a file system
- Ignoring the established CDS limits on a file system
- Validating the operating system targets for a file system
- Displaying the CDS status of a file system
- Migrating a file system one time
- Migrating a file system on an ongoing basis
- When to convert a file system
- Converting the byte order of a file system
- Alignment value and block size
- Migrating a snapshot volume
- Migrating from Oracle ASM to Veritas File System
- Section VIII. Veritas InfoScale 4K sector device support solution
- Section IX. REST API support
- Support for configurations and operations using REST APIs
- Support for InfoScale operations using REST APIs
- Supported operations
- Configuring the REST server
- Security considerations for REST API management
- Authorization of users for performing operations using REST APIs
- Reconfiguring the REST server
- Configuring HA for the REST server
- Accessing the InfoScale REST API documentation
- Unconfiguring the REST server
- Troubleshooting information
- Limitations
- Support for configurations and operations using REST APIs
- Section X. Reference
Recovering from logical corruption
You can use the preserved snapshot image in case of primary storage corruption. You must identify the most recent snapshot that is not affected by the logical corruption.
To identify the most recent valid snapshot
- For each snapshot, starting from the most recent to the oldest, verify the snapshot image. Create a space-optimized snapshot of the point-in-time copy to generate a synthetic replica of the point-in-time image.
# vxsnap -g appdg make source=sosnapappvol${ CURIDX}/new=syn-appvol/cache=snapcache/sync=no - Mount the synthetic replica and verify the data.
If a synthetic replica is corrupted, proceed to 3.
When you identify a synthetic replica that is not corrupted, you can proceed to the recovery steps.
- Unmount the synthetic replica, remove it and go back to verify the next most recent point-in-time copy. Use the following command to dissociate the synthetic replica and remove it:
# vxsnap -g appdg dis syn-appvol # vxedit -g appdg -rf rm syn-appvol
When you find the most recent uncorrupted snapshot, use it to restore the primary volume.
To recover from logical corruption
- If the application is running on the primary volume, stop the application.
- Unmount the application volume.
- Restore the primary volume from the synthetic replica.
# vxsnap -g appdg restore appvol source=syn-appvol
- Resume the application:
Mount the primary volume.
Verify the content of the primary volume.
Restart the application.