Brocade Converged Enhanced Ethernet Administrator's Guide v6.1.2_cee (53-1001258-01, June 2009)
Table Of Contents
- Contents
- Figures
- Tables
- About This Document
- Introducing FCoE
- Using the CEE CLI
- In this chapter
- CEE CLI configuration guidelines and restrictions
- Using the CEE command line interface (CLI)
- CEE CLI RBAC permissions
- Accessing the CEE CLI through the console interface or through a Telnet session
- Accessing the CEE CLI from the Fabric OS shell
- Accessing CEE CLI command modes
- Using CEE CLI keyboard shortcuts
- Displaying CEE CLI commands and command syntax
- Using CEE CLI command completion
- CEE CLI command syntax conventions
- Using CEE CLI command output modifiers
- Configuring VLANs Using the CEE CLI
- In this chapter
- VLAN overview
- Ingress VLAN filtering
- VLAN configuration guidelines and restrictions
- Default VLAN configuration
- VLAN configuration procedures
- Enabling and disabling a CEE interface
- Configuring the MTU on a CEE interface
- Creating a VLAN interface
- Configuring a VLAN interface to forward FCoE traffic
- Configuring a CEE interface as a Layer 2 switch port
- Configuring a CEE interface as an access interface or a trunk interface
- Configuring VLAN classifier rules
- Configuring VLAN classifier groups
- Associating a VLAN classifier group to a CEE interface
- Clearing VLAN counter statistics
- Displaying VLAN information
- Configuring the MAC address table
- Configuring STP, RSTP, and MSTP using the CEE CLI
- In this chapter
- STP overview
- RSTP overview
- MSTP overview
- STP, RSTP, and MSTP configuration guidelines and restrictions
- Default STP, RSTP, and MSTP configuration
- STP, RSTP, and MSTP configuration procedures
- STP, RSTP, and MSTP-specific configuration procedures
- STP and RSTP-specific configuration procedures
- RSTP and MSTP-specific configuration procedures
- MSTP-specific configuration procedures
- 10-Gigabit Ethernet CEE interface-specific configuration
- Global STP, RSTP, and MSTP-related configuration procedures
- Clearing STP, RSTP, and MSTP-related information
- Displaying STP, RSTP, and MSTP-related information
- Configuring Link Aggregation using the CEE CLI
- Configuring LLDP using the CEE CLI
- Configuring ACLs using the CEE CLI
- In this chapter
- ACL overview
- Default ACL configuration
- ACL configuration guidelines and restrictions
- ACL configuration procedures
- Creating a standard MAC ACL and adding rules
- Creating an extended MAC ACL and adding rules
- Modifying a MAC ACL
- Removing a MAC ACL
- Reordering the sequence numbers in a MAC ACL
- Applying a MAC ACL to a CEE interface
- Applying a MAC ACL to a VLAN interface
- Clearing MAC ACL counters
- Displaying MAC ACL information
- Configuring QoS using the CEE CLI
- Configuring FCoE using the Fabric OS CLI
- Administering the switch
- Configuring RMON using the CEE CLI
- Index
82 Converged Enhanced Ethernet Administrator’s Guide
53-1001258-01
DCBX overview
6
DCBX overview
Storage traffic requires a lossless communication which is provided by CEE. The Data Center
Bridging (DCB) Capability Exchange Protocol (DCBX) is used to exchange CEE-related parameters
with neighbors to achieve more efficient scheduling and a priority-based flow control for link traffic.
DCBX uses LLDP to exchange parameters between two link peers; DCBX is built on the LLDP
infrastructure for the exchange of information. DCBX-exchanged parameters are packaged into
organizationally specific TLVs. The DCBX protocol requires an acknowledgement from the other
side of the link, therefore LLDP is turned on in both transmit and receive directions. DCBX requires
version number checking for both control TLVs and feature TLVs.
DCBX interacts with other protocols and features as follows:
• LLDP—LLDP is run in parallel with other Layer 2 protocols such as RSTP and LACP. DCBX is built
on the LLDP infrastructure to communicate capabilities supported between link partners. The
DCBX protocol and feature TLVs are treated as a superset of the LLDP standard.
• QoS management—DCBX capabilities exchanged with a link partner are passed down to the
QoS management entity to set up the Brocade 8000 CEE switch to control the scheduling and
priority-based flow control in the hardware.
The DCBX standard is subdivided into two features sets:
• “Enhanced Transmission Selection (ETS)”
• “Priority Flow Control (PFC)”
Enhanced Transmission Selection (ETS)
In a converged network, different traffic types affect the network bandwidth differently. The
purpose of ETS is to allocate bandwidth based on the different priority settings of the converged
traffic. For example, Inter-process communications (IPC) traffic can use as much bandwidth as
needed and there is no bandwidth check; LAN and SAN traffic share the remaining bandwidth.
Table 13 shows three traffic groups: IPC, LAN, and SAN. ETS allocates the bandwidth based on
traffic type and also assigns a priority to the three traffic types as follows: Priority 7 traffic is
mapped to priority group 0 which does not get a bandwidth check, priority 2 and priority 3 are
mapped to priority group 1, priorities 6, 5, 4, 1 and 0 are mapped to priority group 2.