Understanding MSFC, PFC and DFC roles in Catalyst 6500 Series Switch
Multilayer Switch Feature Card is the Layer 3 switching engine that sites on the Catalyst Supervisor as a daughter card. The MSFC is an integral part of the Supervisor Engine, providing high performance, multilayer switching and routing intelligence. On the MSFC daughter card, the route processor (RP) is located on the MSFC itself. Equipped with a high performance processor, the MSFC runs layer 2 protocols on one CPU and layer 3 protocols on the second CPU. These include routing protocol support, layer 2 protocols (Spanning Tree Protocol and VLAN Trunking Protocol for example), and security services.
The control plane functions in the Cisco Catalyst 6500 are processed by the MSFC and include handling Layer 3 routing protocols, maintaining the routing table, some access control, flow initiation, and other services not found in hardware. Performance of the control plane is dependent on the type and number of processes running on the MSFC. The MSFC3 can support forwarding rates up to 500Kpps. The MSFC provide a means to perform Multilayer Switching (MLS) and interVLAN routing.
The MSFC builds the Cisco Express Forwarding information Base (FIB) table in software and then downloads this table to the hardware Application-specific-integrated circuits (ASICs) on the PFC and DFC (if present) that make the forwarding decisions for IP unicast and multicast traffic.
MSFC ModelSupervisor Model
Supervisor 1 or Supervisor 1A
Supervisor 1A or Supervisor 2
Supervisor 720 Models
Supervisor 720-10GE Models
The PFC3 is the ASIC-based forwarding engine daughtercard for the Sup720; the DFC3 is the ASIC-based forwarding engine daughtercard for various fabric-enabled linecards (CEF256, CEF720). Contains the ASICs that are used to accelerate Layer 2 and Layer 3 switching, store and process QoS and security ACLs, and maintain NetFlow statistics.
The PFC3/DFC3 generation is built upon a forwarding architecture known as EARL7. Within this generation, there are three different versions - 'A', 'B', and 'BXL' - that are all based on the same fundamental technologies but that each have incremental functionality. 'A' is the standard offering; 'B' is the intermediate option, and 'BXL' is the high-end option.
The PFC contains a Layer 2 and a Layer 3 forwarding engine.
The PFC3 supports hardware based Layer 2 and Layer 3 switching, processing security and QoS ACLs in hardware and the collection of NetFlow statistics.
There are five versions of the Policy Feature Card in use today. The PFC3A , PFC3B, and PFC3BXL are integrated into the Supervisor 720-3A, Supervisor 720-3B and Supervisor 720-3BXL respectively. The PFC3B is the only option for the Supervisor 32, while the PFC3C and PFC3CXL are integrated into the Supervisor 720-10G-3C and Supervisor 720-10G-3CXL.
PFC ModelSupervisor Model
|PFC1||Supervisor 1 or Supervisor 1A|
The Catalyst 6500 architecture supports the use of Distributed Forwarding Cards (DFC). Distributed Forwarding Card is a combo daughter card comprising a MSFC and PFC used by a fabric enabled Cat6500 linecard to perform distributed switching. DFCs are located in linecards, not in Supervisors.
A DFC is used to hold a local copy of the forwarding tables (constructed by the MSFC) along with Security and QoS policies to facilitate local switching on the linecard. The DFC3A is available as an option on CEF256 and CEF720 based linecards. The DFC3B and DFC3BXL were introduced for linecards to operate with the Supervisor 720 equipped with PFC3B and PFC3BXL. The last generation of DFC, the DFC3C, is available as an option on the CEF720 based linecards but are integrated on the latest generation linecards, the WS-X6708 and WS-X6716.
It is important to note that there are some operational considerations that can impact the ability of the Catalyst 6500 system to provide specific QoS features. This can happen when you mix different generations of PFC's and DFC's together. The rule is that the system will operate at the lowest common feature denominator
|DFC3A||Normal Operation||PFC3B operates as a PFC3A||PFC3BXL operates as a PFC3A||PFC3C operates as a PFC3A||PFC3CXL operates as a PFC3A|
|DFC3B||DFC3B operates as a DFC3A||Normal Operation||PFC3BXL operates as a PFC3B||PFC3C operates as a PFC3A||PFC3CXL operates as a PFC3B|
|DFC3BXL||DFC3BXL operates as a DFC3A||DFC3BXL operates as a DFC3B||Normal Operation||PFC3C operates as a PFC3BXL||PFC3CXL operates as a PFC3BXL|
|DFC3C||DFC3C operates as a DFC3A||DFC3C operates as a DFC3B||DFC3C operates as a DFC3B and PFC3BXL operates as a PFC3B|
|PFC3CXL operates as a PFC3C|
|DFC3CXL operates as a DFC3A||DFC3CXL operates as a DFC3B||DFC3CXL operates as a DFC3BXL||DFC3CXL operates as a DFC3C||Normal Operation|
The primary MSFC3 will calculate, then push down a FIB table (Forwarding Information Base) giving the DFC3x its layer 3 forwarding tables. The MSFC3 will also push down a copy of the QoS policies so that they are also local to the line card. Subsequent to this, local switching decisions can reference the local copy of any QoS policies providing hardware QoS processing speeds and yielding higher levels of performance though distributed switching.
Performance is the biggest and most obvious reason to implement DFCs. You move from a 30 Mpps centralized forwarding system anywhere up to a 400 Mpps distributed forwarding system. This forwarding performance is for all L2 bridging, L3 routing, ACLs, QoS, and Netflow features, i.e., not just L3.
The performance benefit of a DFC is most applicable when you use the 67xx series modules. This is because these modules have enough ports and bandwidth to generate much more than the 30Mpps centralized forwarding engine has available. A 67xx-series module without a DFC is subject to the same centralized performance characteristics of all other centralized forwarding modules.
DFC also minimize the impact that a classic module has in a system. Classic modules do affect the centralized forwarding performance of a system, limiting the maximum centralized forwarding rate to 15Mpps. Modules enabled with DFCs have their own forwarding engine and are not subject to this performance degradation. If a classic module used, the inclusion of a DFC mitigates any performance issues/concerns. Any non-DFC modules are still subject to the available 15 Mpps of forwarding available when a classic-module is present.
Packet Forwarding is done on the ingress forwarding engine. Therefore, packets coming into the ports on the Sup720-3B will have forwarding done on the PFC3B of the Supervisor. Packets coming into ports of line cards with DFC3s will have the forwarding done on the DFC3. Packets coming into ports of line cards with CFCs will have the forwarding done on the PFC3B of the Supervisor. The MSFC3 only does forwarding in the cases where the PFC3 or DFC3 cannot make the forwarding decision. Some of these cases include when traffic has IP Options set, when ACLs are applied to an interface but the ACL is not programmed into the ACL TCAM for some reason, when packets have TTL expiration, when packets hit an ACE with the "log" keyword, and others.
CFC is a centralized forwarding card for the switching modules which makes IPv4 Routing over the PFC. CFC does not do local forwarding, the forwarding is done by the PFC in the Supervisor. As the forwarding is centralized, the PFC performance, FIB entries, ACL lables are shared among the line cards that uses the Supervisor PFC for forwrding. WS-F6700-CFC is the CFC card used on WS-X67xx Ethernet Modules. This daughter card is supported only by the Supervisor Engine 720.
Note: CFC or the Centralized Forwarding Card was introduced along with the CEF720 modules. It provides centralized connectivity to the supervisor for look-ups and results. Though the switch fabric is used for the data, but the CFC is responsible to send a look-up request from the Supervisor and then get those results back.