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
472 Fabric OS Administrator’s Guide
53-1001763-02
FC Router port cost configuration
21
FC routers optimize the usage of the router port links by directing traffic to the link with the
smallest router port cost. The FC router port cost is similar to the link cost setting available on
E_Ports, which allows you to customize traffic flow. The router port link cost values are either 1000
or 10,000. The router module chooses the router port path based on the lowest cost for each FID
connection. If multiple paths exist where one path costs lower than the others, then the lowest cost
path is used. If exchange-based routing has not been disabled and multiple paths exist with the
same lowest cost, there will be load sharing over these paths.
The router port cost feature optimizes the usage of the router port links by directing the traffic to a
link with a smaller cost.
Every IFL has a default cost. The default router port cost values are:
• 1000 for legacy (v5.1 or XPath FCR) IFL
• 1000 for EX_Port IFL
• 10,000 for VEX_Port IFL
The FCR router port cost settings are 0, 1000, or 10,000. If the cost is set to 0, the default cost will
be used for that IFL. The FC router port cost is persistent and is saved in the existing port
configuration file.
Router port cost is passed to other routers in the same backbone. Link costs from the front domain
to the translate (xlate) domain remain at 10,000. You can use the lsDbShow from the edge fabric to
display these link costs.
Port cost considerations
The router port cost has the following considerations:
• Router port sets are defined as follows:
- 0–7 and FCIP Tunnel 16–23
- 8–15 and FCIP Tunnel 24–31
More than two router port sets can exist in a Brocade 48000, Brocade DCX, or Brocade DCX-4S
with two FR4-18i blades.
• The router port cost does not help distinguish one IFL (or EX_ and VEX_Port link) from another,
if all the IFLs are connected to the same port set. Therefore, if you connect IFL1 and IFL2 to the
same edge fabric in port set 0–7 and then configure them to different router port costs, traffic
is still balanced across all the IFLs in the same port set.
• Use proper SAN design guidelines to connect the IFLs to different port sets for effective router
port cost use. For example, if both a low-speed IFL and a high-speed IFL are going to the same
edge fabric, connect the lower router cost IFLs to a separate port group (for example ports 0–
7) than the higher router cost IFLs (for example ports 8–15). For VEX_Ports, you would use
ports in the range of 16–23 or 24–31.
You can connect multiple EX_Ports or VEX_Ports to the same edge fabric. The EX_Ports can all be
on the same FC router, or they can be on multiple routers. Multiple EX_Ports create multiple paths
for frame routing. Multiple paths can be used in two different, but compatible, ways:
• Failing over from one path to another.
• Using multiple paths in parallel to increase effective data transmission rates.