HP-UX Virtual Partitions Administrator's Guide (includes A.04.06 and A.05.04)
Table Of Contents
- HP-UX Virtual Partitions Administrator’s Guide
- Table of Contents
- About This Document
- 1 Introduction
- 2 How vPars and Its Components Work
- Partitioning Using vPars
- vPars Monitor and Database
- Boot Sequence
- Virtual Consoles
- Security
- EFI and Integrity Notes
- Integrity Differences Relative to PA-RISC
- Comparing vPars on PA-RISC and Integrity
- Comparing vPars Versions
- Resource Migration and Required States
- Transitioning from vPars A.03.xx to vPars A.04.xx/A.05.xx (CPU Syntax and Rules)
- 3 Planning Your System for Virtual Partitions
- Full ioscan Output of Non-Cellular System Named winona
- Full ioscan Output of Cellular (nPartitionable) System Named keira
- Planning, Installing, and Using vPars with an nPartitionable Server
- Planning Your Virtual Partitions
- Mixed HP-UX 11i v1/v2 vPars Environments in vPars A.04.05
- Mixed HP-UX 11i v2/v3 vPars Environments in vPars A.05.xx
- Mixed HP-UX 11i v1/v2/v3 vPars Environments in vPars A.05.03
- 4 Installing, Updating, or Removing vPars and Upgrading Servers with vPars
- Notes, Cautions, and Other Considerations Before You Update or Install vPars
- Bundle Names
- Setting Up the Ignite-UX Server
- Ignite-UX, the LAN, the LAN card, and vparboot -I
- Updating from vPars A.04.xx to A.05.xx
- Updating from vPars A.03.xx to Mixed HP-UX 11i v1/v2 vPars (A.03.05 and A.04.05) Environment
- Migrating from vPars A.03.xx to Mixed HP-UX 11i v1/v2/v3 vPars (A.03.05, A.04.02 or later, A.05.03)
- Updating from vPars A.04.xx to Mixed HP-UX 11i v2/v3 vPars (A.04.xx and A.05.xx) Environment
- Updating from vPars A.03.xx to A.05.xx
- Updating from vPars A.03.xx to A.04.xx
- Updating vPars A.03.xx to vPars A.03.05
- Updating from vPars (A.02.xx or A.03.xx) to A.03.xx
- Applying a vPars Sub-System Patch
- Upgrading Integrity Servers from the sx1000 to sx2000 Chipset
- Upgrading HP 9000 Servers from the sx1000 to sx2000 Chipset
- Upgrading Backplanes from PCI to PCI-X
- Updates Involving VPARSBASE
- Installing vPars with Ignite-UX on PA-RISC
- Installing vPars with Ignite-UX on Integrity
- Installing vPars with Software Distributor
- Removing the vPars Product
- 5 vPars Monitor and Shell Commands
- Notes on Examples in this Chapter
- Modes: Switching between nPars and vPars Modes (Integrity Only)
- EFI Boot Disk Paths, including Disk Mirrors, and vparefiutil (Integrity Only)
- vPars Monitor: Booting the vPars Monitor
- vPars Monitor: Accessing the vPars Monitor Prompt
- vPars Monitor: Using vPars Monitor Commands
- vPars Monitor: Using the vPars Monitor Commands from ISL or EFI
- Commands: vPars Manpages
- Commands: vPars Commands Logging
- Commands: Displaying vPars Monitor and Resource Information (vparstatus)
- Virtual Partition States
- vparstatus Output Examples
- vparstatus: Summary Information
- vparstatus: Verbose Information
- vparstatus: Available Resources
- vparstatus: CPU Information on vPars A.04/A.05
- vparstatus: Dual-Core CPUs
- vparstatus: Pending Migrating CPUs Operations
- vparstatus: Pending Migrating Memory Operations
- vparstatus: Base and Float Memory Amounts
- vparstatus: Pending nPartition Reboot for Reconfiguration
- vparstatus: vPars Monitor and Database Information
- Managing: Creating a Virtual Partition
- Managing: Removing a Virtual Partition
- Managing: Modifying Attributes of a Virtual Partition
- Booting a Virtual Partition
- Shutting Down or Rebooting a Virtual Partition
- Shutting Down or Rebooting the nPartition (Or Rebooting the vPars Monitor)
- Setboot and System-wide Stable Storage
- Using Primary and Alternate Boot Paths
- Autoboot
- Single-User Mode
- Other Boot Modes
- Resetting a Virtual Partition
- Using an Alternate Partition Database File
- Managing Resources With Only One Virtual Partition
- 6 CPU, Memory, and I/O Resources (A.05.xx)
- I/O: Topics
- I/O: Concepts and Functionality
- I/O: Adding or Deleting LBAs
- I/O: Allocation Notes
- Memory: Topics
- Memory: Concepts and Functionality
- Memory: Assigning (Adding) or Deleting by Size (ILM)
- Memory: Assigning (Adding) Or Deleting by Size (CLM)
- Memory: Assigning (Adding) Or Deleting by Address Range
- Memory: Available and Assigned Amounts
- Memory: Converting Base Memory to Float Memory
- Memory: Granularity Concepts
- Memory: Granularity Issues (Integrity and PA-RISC)
- Memory: Setting the Granularity Values (Integrity)
- Memory: Setting the Granularity Values (PA-RISC)
- Memory: Notes on vPars Syntax, Rules, and Output
- CPU: Topics
- CPU: Concepts and Functionality
- CPU: Specifying Min and Max Limits
- CPU: Adding and Deleting by Total
- CPU: Adding or Deleting by CLP (Cell Local Processor)
- CPU: Adding or Deleting by Hardware Path
- CPU: Notes on vPars Syntax, Rules, and Output
- CPU: Dual-Core Processors
- CPU: Hyperthreading ON/OFF (HT ON/OFF)
- CPUs: Managing I/O Interrupts
- CPU: CPU Monitor (Formerly Known As LPMC Monitor)
- Memory, CPU: Canceling Pending Operations
- 7 CPU, Memory, and I/O Resources (A.04.xx)
- I/O: Concepts
- I/O: Adding or Deleting LBAs
- I/O: Allocation Notes
- Memory: Concepts and Functionality
- Memory: Assigning by Size (ILM)
- Memory: Assigning by Size (CLM)
- Memory: Specifying Address Range
- Memory: Granularity Concepts
- Granularity Issues (Integrity and PA-RISC)
- Memory: Choosing a Granularity Value and Boot Time (Integrity)
- Memory: Setting the Granularity Values (Integrity)
- Memory: Setting the Granularity Values (PA-RISC)
- Memory: Allocation Notes
- CPU
- CPU: Boot Processor and Dynamic CPU Definitions
- CPU: Specifying Min and Max Limits
- CPU: Adding and Deleting by Total
- CPU: Adding or Deleting by CLP (Cell Local Processor)
- CPU: Adding or Deleting by Hardware Path
- CPU: Syntax, Rules, and Notes
- Managing I/O Interrupts
- CPU: Using iCAP (Instant Capacity on Demand) with vPars (vPars A.04.xx and iCAP B.07)
- CPU: Dual-Core Processors
- CPU: CPU Monitor (Formerly Known As LPMC Monitor)
- 8 CPU, Memory, and I/O Resources (A.03.xx)
- I/O: Concepts
- I/O: Adding or Deleting LBAs
- I/O: Allocation Notes
- Memory: Concepts and Functionality
- Memory: Assigning by Size (ILM)
- Memory: Specifying Address Range
- Memory: Allocation Concepts and Notes
- CPU
- CPU: Specifying Min and Max Limits
- CPU: Bound and Unbound
- CPU: Determining Whether to Use Bound or Unbound
- CPU: Determining When to Specify a Hardware Path for a Bound CPU
- CPU: Adding and Removing Bound CPUs
- CPU: Adding a CPU as a Bound CPU
- CPU: Removing a Bound CPU
- CPU: Adding, Removing, and Migrating Unbound CPUs
- CPU: Managing I/O Interrupts
- CPU: Dual-Core Processors
- CPU: CPU Monitor (Formerly Known As LPMC Monitor)
- 9 nPartition Operations
- Basic Conceptual Points on using vPars within nPartitions
- nPartition Information
- Setting Hyperthreading (HT ON/OFF) and cpuconfig Primer
- Rebooting and Reconfiguring Conceptual Points
- Reconfiguring the nPartition
- Putting an nPartition into an Inactive State and Other GSP Operations
- Configuring CLM for an nPartition
- 10 Crash Processing and Recovery
- Crash Processing
- Network and Tape Recovery
- Using make_net_recovery within a vPars Environment
- Using make_tape_recovery Outside of a vPars Environment
- Using make_tape_recovery and Dual-media Boot
- Using make_tape_recovery within a vPars Environment
- Expert Recovery
- 11 vPars Flexible Administrative Capability
- Synopsis
- Terms and Definitions
- Flexible Administrative Capability Commands
- monadmin
- vparadmin
- Persistence across vPars Monitor Reboots
- vPars Commands
- Example vPars Monitor Scenario (monadmin)
- Example HP-UX Shell Scenario (vparadmin)
- A Command Successfully Executed
- A Command Not Executed Due to the Flexible Administrative Capability Feature
- Adding a Virtual Partition to the Designated-admin Virtual Partition List
- Deleting a Virtual Partition to the Designated-admin Virtual Partition List
- Listing the Virtual Partitions in the Designated-admin Virtual Partition List
- Changing the Flexible Administrative Capability Password
- Determining whether Flexible Administrative Capability is ON or OFF
- 12 Virtual Partition Manager (A.03.xx)
- A LBA Hardware Path to Physical I/O Slot Correspondence (PA-RISC only)
- B Problem with Adding Unbound CPUs to a Virtual Partition (A.03.xx)
- C Calculating the Size of Kernels in Memory (PA-RISC only)
- D Memory Usage with vPars in nPartitions
- E Moving from a Standalone to vPars
- F Supported Configurations for Memory Migration
- Glossary
- Index
CPU: CPU Monitor (Formerly Known As LPMC Monitor)
The CPU Monitor (a part of the diagnostic tool Event Monitor Services (EMS) and not a part of
the vPars Monitor) is designed to monitor cache parity errors within the CPUs on the system.
With its Dynamic Processor Resilience (DPR), if the CPU Monitor detects a pre-determined
number of errors, the CPU Monitor will deactivate a CPU for the current boot session. If the
problems are severe enough, the CPU Monitor will deconfigure the socket for the next boot of
the system.
Deactivation of a CPU means that the OS will attempt to no longer use the CPU by migrating all
threads off the CPU. Deactivation of a CPU is not persistent across an OS or system reboot.
Deconfiguration of a socket means that the EMS issues a firmware call, marking the socket for
deconfiguration on the next system boot. On the next system boot, none of the cores in the target
socket are visible to either the OS in standalone mode or the OS instances of the virtual partitions.
The deconfiguration is persistent across system boots.
Note here two items:
• a deactivation of a CPU does not mean a deconfiguration of its socket. The CPU Monitor is
able to determine whether the CPU needs to be deactivated or whether it needs to take
further action and deconfigure the socket.
• reboot of a virtual partition is not the same as a reboot of the system (the entire box or
nPartition).
The exceptions to the deactivation of CPUs are the boot processor of each OS instance (the boot
processor has a logical instance of zero) and the last CPU in a cell or nPartition. The exception
to the deconfiguration of sockets is that the last remaining socket will not be deconfigured
(otherwise, the system could not boot).
If any spare iCAP (formerly known as iCOD) or PPU CPUs are available, the necessary number
of CPUs will be activated to replace the CPUs deactivated.
NOTE: On a vPars system, for bound CPUs, the virtual partition boots with the CPU marked
for deconfiguration. For unbound CPUs, the vPars Monitor will attempt to replaced the marked
CPUs with a working CPU; however, if no working CPUs are available, the vPars Monitor
automatically reduces the unbound CPU number for that virtual partition in the vPars database
and allows the virtual partition to boot with the working CPUs.
Dual-core processors have two CPUs (that is, cores) per processor. Deactivation happens on a
CPU level, but deconfiguration happens at the socket level. If a processor’s socket is deconfigured,
both CPUs sharing the socket will be unavailable.
264 CPU, Memory, and I/O Resources (A.03.xx)