Administrator Guide
Table Of Contents
- Contents
- Figures
- Tables
- About This Document
- Understanding Fibre Channel Services
- Performing Basic Configuration Tasks
- Performing Advanced Configuration Tasks
- Routing Traffic
- Managing User Accounts
- Configuring Protocols
- Configuring Security Policies
- In this chapter
- ACL policies overview
- ACL policy management
- FCS policies
- DCC policies
- SCC policies
- Authentication policy for fabric elements
- IP Filter policy
- Creating an IP Filter policy
- Cloning an IP Filter policy
- Displaying an IP Filter policy
- Saving an IP Filter policy
- Activating an IP Filter policy
- Deleting an IP Filter policy
- IP Filter policy rules
- IP Filter policy enforcement
- Adding a rule to an IP Filter policy
- Deleting a rule to an IP Filter policy
- Aborting an IP Filter transaction
- IP Filter policy distribution
- Policy database distribution
- Management interface security
- Maintaining the Switch Configuration File
- Installing and Maintaining Firmware
- In this chapter
- Firmware download process overview
- Preparing for a firmware download
- Firmware download on switches
- Firmware download on an enterprise-class platform
- Firmware download from a USB device
- FIPS Support
- Test and restore firmware on switches
- Test and restore firmware on enterprise-class platforms
- Validating a firmware download
- Managing Virtual Fabrics
- In this chapter
- Virtual Fabrics overview
- Logical switch overview
- Logical fabric overview
- Management model for logical switches
- Account management and Virtual Fabrics
- Supported platforms for Virtual Fabrics
- Limitations and restrictions of Virtual Fabrics
- Enabling Virtual Fabrics mode
- Disabling Virtual Fabrics mode
- Configuring logical switches to use basic configuration values
- Creating a logical switch or base switch
- Executing a command in a different logical fabric context
- Deleting a logical switch
- Adding and removing ports on a logical switch
- Displaying logical switch configuration
- Changing the fabric ID of a logical switch
- Changing a logical switch to a base switch
- Setting up IP addresses for a Virtual Fabric
- Removing an IP address for a Virtual Fabric
- Configuring a logical switch to use XISLs
- Changing the context to a different logical fabric
- Creating a logical fabric using XISLs
- Administering Advanced Zoning
- In this chapter
- Special zones
- Zoning overview
- Broadcast zones
- Zone aliases
- Zone creation and maintenance
- Default zoning mode
- Zoning database size
- Zoning configurations
- Creating a zoning configuration
- Adding zones (members) to a zoning configuration
- Removing zones (members) from a zone configuration
- Enabling a zone configuration
- Disabling a zone configuration
- Deleting a zone configuration
- Clearing changes to a configuration
- Viewing all zone configuration information
- Viewing selected zone configuration information
- Viewing the configuration in the effective zone database
- Clearing all zone configurations
- Zone object maintenance
- Zoning configuration management
- Security and zoning
- Zone merging scenarios
- Traffic Isolation Zoning
- In this chapter
- Traffic Isolation Zoning overview
- Enhanced TI zones
- Traffic Isolation Zoning over FC routers
- General rules for TI zones
- Supported configurations for Traffic Isolation Zoning
- Limitations and restrictions of Traffic Isolation Zoning
- Admin Domain considerations for Traffic Isolation Zoning
- Virtual Fabric considerations for Traffic Isolation Zoning
- Traffic Isolation Zoning over FC routers with Virtual Fabrics
- Creating a TI zone
- Modifying TI zones
- Changing the state of a TI zone
- Deleting a TI zone
- Displaying TI zones
- Setting up TI over FCR (sample procedure)
- Administering NPIV
- Interoperability for Merged SANs
- In this chapter
- Interoperability overview
- Connectivity solutions
- Domain ID offset modes
- McDATA Fabric mode configuration restrictions
- McDATA Open Fabric mode configuration restrictions
- Interoperability support for logical switches
- Switch configurations for interoperability
- Zone management in interoperable fabrics
- Frame Redirection in interoperable fabrics
- Traffic Isolation zones in interoperable fabrics
- Brocade SANtegrity implementation in mixed fabric SANS
- E_Port authentication between Fabric OS and M-EOS switches
- FCR SANtegrity
- FICON implementation in a mixed fabric
- Fabric OS version change restrictions in an interoperable environment
- Coordinated Hot Code Load
- McDATA-aware features
- McDATA-unaware features
- Supported hardware in an interoperable environment
- Supported features in an interoperable environment
- Unsupported features in an interoperable environment
- Managing Administrative Domains
- In this chapter
- Administrative Domains overview
- Admin Domain management for physical fabric administrators
- Setting the default zoning mode for Admin Domains
- Creating an Admin Domain
- User assignments to Admin Domains
- Removing an Admin Domain from a user account
- Activating an Admin Domain
- Deactivating an Admin Domain
- Adding members to an existing Admin Domain
- Removing members from an Admin Domain
- Renaming an Admin Domain
- Deleting an Admin Domain
- Deleting all user-defined Admin Domains
- Deleting all user-defined Admin Domains non-disruptively
- Validating an Admin Domain member list
- SAN management with Admin Domains
- CLI commands in an AD context
- Executing a command in a different AD context
- Displaying an Admin Domain configuration
- Switching to a different Admin Domain context
- Admin Domain interactions with other Fabric OS features
- Admin Domains, zones, and zone databases
- Admin Domains and LSAN zones
- Configuration upload and download in an AD context
- Administering Licensing
- Monitoring Fabric Performance
- In this chapter
- Advanced Performance Monitoring overview
- End-to-end performance monitoring
- Frame monitoring
- ISL performance monitoring
- Top Talker monitors
- Adding a Top Talker monitor on an F_Port
- Adding Top Talker monitors on all switches in the fabric (fabric mode)
- Displaying the top n bandwidth-using flows on an F_Port
- Displaying top talking flows for a given domain ID (fabric mode)
- Deleting a Top Talker monitor on an F_Port
- Deleting the fabric mode Top Talker monitors
- Limitations of Top Talker monitors
- Trunk monitoring
- Displaying end-to-end and ISL monitor counters
- Clearing end-to-end and ISL monitor counters
- Saving and restoring monitor configurations
- Performance data collection
- Optimizing Fabric Behavior
- In this chapter
- Adaptive Networking overview
- Ingress Rate Limiting
- QoS: SID/DID traffic prioritization
- QoS zones
- QoS on E_Ports
- QoS over FC routers
- Virtual Fabric considerations for traffic prioritization
- High availability considerations for traffic prioritization
- Supported configurations for traffic prioritization
- Upgrade considerations for traffic prioritization
- Limitations and restrictions for traffic prioritization
- Setting traffic prioritization
- Setting traffic prioritization over FC routers
- Disabling QoS
- Bottleneck detection
- Supported configurations for bottleneck detection
- How bottlenecks are reported
- Limitations of bottleneck detection
- High availability considerations for bottleneck detection
- Upgrade and downgrade considerations for bottleneck detection
- Trunking considerations for bottleneck detection
- Virtual Fabrics considerations for bottleneck detection
- Access Gateway considerations for bottleneck detection
- Enabling bottleneck detection on a switch
- Excluding a port from bottleneck detection
- Displaying bottleneck detection configuration details
- Changing bottleneck alert parameters
- Displaying bottleneck statistics
- Disabling bottleneck detection on a switch
- Managing Trunking Connections
- Managing Long Distance Fabrics
- In this chapter
- Long distance fabrics overview
- Extended Fabrics device limitations
- Long distance link modes
- Configuring an extended ISL
- Buffer credit management
- Buffer-to-Buffer flow control
- Optimal buffer credit allocation
- Fibre Channel gigabit values reference definition
- Allocating buffer credits based on full-size frames
- Allocating buffer credits based on average-size frames
- Allocating buffer credits for F_Ports
- Displaying the remaining buffers in a port group
- Buffer credits for each switch model
- Maximum configurable distances for Extended Fabrics
- Buffer credit recovery
- Using the FC-FC Routing Service
- In this chapter
- FC-FC routing service overview
- Integrated Routing
- Fibre Channel routing concepts
- Setting up the FC-FC routing service
- Backbone fabric IDs
- FCIP tunnel configuration
- Inter-fabric link configuration
- FC Router port cost configuration
- EX_Port frame trunking configuration
- LSAN zone configuration
- Use of Admin Domains with LSAN zones and FCR
- Zone definition and naming
- LSAN zones and fabric-to-fabric communications
- Controlling device communication with the LSAN
- Setting the maximum LSAN count
- Configuring backbone fabrics for interconnectivity
- HA and downgrade considerations for LSAN zones
- LSAN zone policies using LSAN tagging
- LSAN zone binding
- Proxy PID configuration
- Fabric parameter considerations
- Inter-fabric broadcast frames
- Resource monitoring
- FC-FC Routing and Virtual Fabrics
- Upgrade and downgrade considerations for FC-FC routing
- Displaying the range of output ports connected to xlate domains
- M-EOS Migration Path to Fabric OS
- Inband Management
- Port Indexing
- FIPS Support
- Hexadecimal
- Index
36 Fabric OS Administrator’s Guide
53-1001763-02
PIDs and PID binding overview
3
Core PID addressing mode
Core PID is the default PID format for Brocade platforms. It uses the entire 24-bit address space of
the domain, area_ID, and AL_PA to determine an objects address within the fabric.
The Core PID is a 24-bit address built from the following three 8-bit fields:
• domain, written in hex and the numeric range is from 01-ee (1-239)
• area_ID, written in hex and the numeric range is from 01-ff (1-255)
• AL_PA
For example, if a device is assigned an address of 0f1e00, the following would apply:
• 0f is the domain ID.
• 1e is the area ID.
• 00 is the assigned AL_PA.
From this information, you can determine which switch the device resides on from the domain ID,
which port the device is attached to from the area_ID, and if this device is part of a loop from the
AL_PA number.
For more information on reading and converting hexadecimal, refer to Appendix E, “Hexadecimal”.
Fixed addressing mode
Fixed addressing mode is the default addressing mode used in all platforms that do not have
Virtual Fabrics enabled. When Virtual Fabrics is enabled on the Brocade DCX and DCX-4S, fixed
addressing mode is used only on the default partition. With fixed addressing mode enabled, each
port has a fixed address assigned by the system based on the port number. This address does not
change unless you choose to swap the address using the portSwap command.
10-bit addressing mode
This is the default mode for all the logical switches created in the Brocade DCX and DCX-4S
enterprise-class platforms. This addressing scheme is flexible to support a large number of
F_Ports. In the regular 10-bit addressing mode, the portAddress
--auto command supports
addresses from 0x00 to 0x8F.
NOTE
The default switch in the Brocade DCX and DCX-4S enterprise-class platform still uses the fixed
addressing mode in order to support 4 Gbps blades.
The 10-bit addressing mode utilizes the 8-bit area_ID and the borrowed upper two bits from the
AL_PA portion of the PID. Areas 0x00 through 0x8F use only 8 bits for the port address and support
up to 256 NPIV devices. This means a logical switch can support up to 144 ports that can each
support 256 devices. Areas 0x90 through 0xFF use an additional two bits from ALPA for the port
address. Hence these ports support only 64 NPIV devices per port.
10-bit addressing mode allows for the following functionalities:
• PID is dynamically allocated only when the port is first moved to a logical switch and thereafter
it is persistently maintained.
• Shared area limitations are removed on 48-port blades.