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Displays the storage capacity of the selected storage class and Storage Domain that is available for the logical volume. The graph uses colored bars of different thicknesses to indicate the capacity status of the logical volume you are creating as well as the overall system capacity.
Specifies that the data is stored on solid state drives (SSDs) that are optimized for the performance of balanced read and write operations.
Specifies that the data is stored on SSDs that are optimized for the performance of capacity and for read operations. The write performance for this Storage Class is sacrificed somewhat to achieve the optimizations for read performance and for capacity.
Specifies that the data is stored on high-speed hard disk drives (HDDs). This Storage Class sacrifices some capacity to reduce the access time and the latency of the read operations and of the write operations.
Specifies that the data is stored on high-capacity, rotating HDDs. This Storage Class optimizes capacity at some sacrifice of speed. For a storage system that does not include tape storage as an option, this Storage Class always provides the lowest cost for each GB of capacity.
Specifies the name of the storage domain associated with the LUN.
Displays a dialog that lists the available Storage Domains.
Must be unique across the Oracle FS System
Must be 82 or fewer UTF characters
Must be 255 or fewer ASCII characters
Allows you to assign the LUN to a volume group.
Opens the Manage Volume Groups dialog, which allows you to create a volume group.
Specifies whether the logical volume uses a custom set of QoS properties. Selecting this option disables the remaining QoS properties on the page.
Opens the View Storage Profiles dialog, which allows you to review the profile details.
Specifies the category of physical media on which the logical volume resides.
Specifies that the data is stored on solid state drives (SSDs) that are optimized for the performance of balanced read and write operations.
Specifies that the data is stored on SSDs that are optimized for the performance of capacity and for read operations. The write performance for this Storage Class is sacrificed somewhat to achieve the optimizations for read performance and for capacity.
Specifies that the data is stored on high-speed hard disk drives (HDDs). This Storage Class sacrifices some capacity to reduce the access time and the latency of the read operations and of the write operations.
Specifies that the data is stored on high-capacity, rotating HDDs. This Storage Class optimizes capacity at some sacrifice of speed. For a storage system that does not include tape storage as an option, this Storage Class always provides the lowest cost for each GB of capacity.
Indicates that the read requests and the write requests operate on the data mostly by accessing the records one after the other in a physical order.
Indicates that the read requests and the write requests operate on the data mostly by accessing the records in an arbitrary order.
Indicates that the read requests and the write requests operate on the data sometimes in sequential order and sometimes in random order.
Indicates that most of the access requests are for read operations.
Indicates that most of the access requests are for write operations.
Indicates that the number of access requests are similar for read operations and for write operations.
Identifies the number of copies of the parity bits that the Oracle FS System creates for the volume
Stores the original user data plus one set of parity bits to help in the recovery of lost data. Access to the data is preserved even after the failure of one drive. Single parity is implemented using RAID 5 technology and is the default redundancy level for the Storage Classes that specify the performance-type media.
Stores the original user data plus two sets of parity bits to help in the recovery of lost data. Access to the data is preserved even after the simultaneous failure of two drives. Double parity is implemented using RAID 6 technology and is the default redundancy level for the Storage Classes that specify the capacity-type media.
Identifies the RAID level associated with the Storage Profile.
Indicates that, in addition to the actual data, one set of parity bits exists for the logical volume. This parity level protects against the loss of one drive. Single parity is implemented as a variant of the RAID 5 storage technology.
Indicates that, in addition to the actual data, two sets of parity bits exist for the logical volume. This parity level protects against the loss of one or two drives with a slight cost to write performance. Double parity is implemented as a variant of the RAID 6 storage technology.
Indicates that no parity bits exist for the volume. Instead, the system writes the data in two different locations. This RAID level protects against the loss of at least one drive and possibly more drives with an improvement of the performance of random write operations. Mirrored RAID is implemented as a variant of the RAID 10 storage technology.
Identifies the read‑ahead policy that the system uses for sequential read operations. The policy determines the amount of additional data, if any, that the system places into the Controller cache. Valid policies:
Indicates that the input requests and the output requests are accessing the data mostly in a random manner or in a mixed sequential and random manner.
Indicates that the input requests and the output requests are accessing the data mostly in a sequential manner and that the workload is biased toward read operations.
Indicates that the input requests and the output requests are mostly sequential and that the workload is biased toward write operations.
Indicates the highest priority for responding to requests in the processing queue. For auto-tiered LUNs, busy LUN extents receive the highest priority when the system migrates the data to the higher-performing storage tiers.
Indicates the next highest priority for responding to requests in the processing queue. For auto-tiered LUNs, busy LUN extents receive the next highest priority when the system migrates the data to the higher-performing storage tiers.
Indicates an intermediate priority for responding to requests in the processing queue. For auto-tiered LUNs, busy LUN extents receive an intermediate priority when the system migrates the data to the higher-performing storage tiers.
Indicates the next to lowest priority for responding to requests in the processing queue. For auto-tiered LUNs, busy LUN extents receive the next to lowest priority when the system migrates the data to the higher-performing storage tiers.
Indicates the lowest priority for responding to requests in the processing queue. For auto-tiered LUNs, busy LUN extents receive the lowest priority when the system migrates the data to the higher-performing storage tiers.
Balances the background copy with the incoming client I/O. This option is the default.
Restricts the amount of work performed on a loaded system. This option is intended to have a minimal impact on client I/O throughput at the expense of longer copy times.
Prioritizes the background copy at the expense of client I/O throughput.
Identifies the maximum capacity to which the logical volume can grow. For a clone, this field identifies how much addressable space is available. Capacity must be greater than or equal to the allocated logical capacity.
Identifies the amount of capacity that is reserved for the logical volume. The reserve capacity must be less than or equal to the maximum capacity.
Disables a portion of the internal data integrity checks for the LUN. Selecting this option disables checking whether any given block of data has the same identity, known as the Logical Block Address (LBA), as that which was written by the host. Data CRC integrity checking is not affected.
If you select the Disable Reference Tag Checking option, then the Use as a Boot LUN option has no effect.
Use as a Boot LUN
Disable Reference Tag Checking
If your host or application has interoperability problems with the Oracle FS System, then you can use the Disable Reference Tag Checking option to temporarily work around the issue.
Modifies the default error response returned to the host or application when a block of data is read that has not been previously written by the host. There is no other effect on the LUN.
Select this option if you have hosts and application that read data blocks that they have not written as part of a validation process, such as preparing the LUN for system boot.
Reading a data block before it is written causes the reference tag check to fail, which returns an error to the host. After receiving this error, the host retries the operation, and inhibits the reference tag check. The Use as a Boot LUN option does not modify the reference tag check. This option only changes the error response because some hosts and applications modify the retry timing depending on the error that is returned. Always try both settings of the Use as a Boot LUN option before using the Disable Reference Tag Checking option.