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An introduction to MPLS and GMPLS (and briefly T-MPLS). Anne-Grethe Kåråsen, Telenor R&I Modified by Steinar Bjørnstad NTNU Two slides on T-MPLS added by Norvald Stol NTNU 2007. Why was MultiProtocol Label Switching (MPLS) designed?.
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An introduction to MPLS and GMPLS (and briefly T-MPLS) Anne-Grethe Kåråsen, Telenor R&I Modified by Steinar Bjørnstad NTNU Two slides on T-MPLS added by Norvald Stol NTNU 2007
Why was MultiProtocol Label Switching (MPLS) designed? • To enhance the performance of the traffic forwarding mechanisms (compared to traditional IP forwarding) • To provide a traffic engineering (TE) capability in IP networks
What is Traffic Engineering (TE)? • TE is concerned with performance optimization of operational networks. • Traffic performance: A major goal of Internet TE is to facilitate efficient and reliable network operations while simultaneously optimizing network resource utilization and traffic performance. • QoS: Traffic oriented performance objectives include the aspects that enhance the QoS of traffic streams. • Resource utilization: Resource oriented performance objectives include the aspects pertaining to the optimization of resource utilization.
The resource problem to solve: • Conventional IGP path computation is selected based upon a simple additive metric. • Bandwidth availability is not taken into account • Some links may be underutilized while others are congested.
A solution to the resource problem Path for R1 to R3 traffic Path for R2 to R3 traffic
MPLS - some main concepts • Uses label switching to forward data • A label is a short fixed length physicallycontiguous identifier which is used toidentify a FEC, usually of local significance. • MPLS path = Label Switched Path (LSP) • Forwarding Equivalence Class (FEC) • A group of IP packets that are forwarded in the same manner • FEC – label mapping in ingress MPLS node • Criteria for assigning packets to FECs are configurable • Next Hop Label Forwarding Entry (NHLFE) • Packets next hop + label operation (swap, push, pop)
The MPLS shim header • The EXP Field is "Experimental" though it is proposed use is to indicate Per Hop Behavior of labeled packets traversing Label Switching Routers. (QoS) • The Stack (S) Field indicates the presence of a label stack. • The Time to Live Field is decremented at each LSR hop and is used to throw away looping packets.
LSP route determination • An LSP must be set up and labels assigned at each hop before traffic forwarding can take place. • There are two kinds of LSPs, based on the method used for determining the route: • control-driven LSPs (hop-by-hop LSPs) • explicitly routed LSPs (ER-LSPs) • A control-driven LSP follows the path that a packet using default IP routing would have used. • An ER-LSP may be specified and controlled so that the network traffic follows a path independent of what is computed by IP routing.
Constraint-based routing • Types of constraints: • Resource related (e.g. bandwidth) • Administrative (e.g. include/exclude certain links) • Resource related and policy related attributes are associated with links. • Link attributes are flooded by the routing protocols along with topology information. • A constraint-based path computation process uses this information when finding paths that satisfy given constraints. • Most used algorithm is Constraint Shortest Path First (CSPF): • Excludes all links that fail to meet constraint • Chooses shortest path that meets constraint • Convenient for online path selection, one LSP at a time
ER-LSPs • Explicit LSP: route is determined at the originating node. When we explicitly route an LSP, we call it an LSP tunnel or a traffic-engineering tunnel. • Explicit route information is carried only at the time of LSP setup, not with each packet forwarded on the LSP. • LSP tunnels are uni-directional. • Can be set up manually or by the use of a signaling protocol.
LSR9 LSR8 LSR3 LSR4 LSR2 ERO=( 5) ERO=(2, 6, 7, 4, 5) ERO=(4, 5) LSR5 ERO=(6, 7, 4, 5) L=21 L=5 ERO=(7, 4, 5) L=10 L=14 LSR1 LSR7 L=21 LSR6 RSVP Path message carried Explicit Route Object (ERO) RSVP Resv message carries Label information (L) ER-LSP setup example using RSVP-TE
Label-Switched Path (LSP) LER IP Packet Label 1 Label 2 Label 3 IP Packet LER LSR LSR IP Packet IP Packet IP Packet IP Forwarding LABEL SWITCHING IP Forwarding MPLS Label Forwarding Example
Protocols for MPLS routing and signaling Routing: • Open Shortest Path First (OSPF) & Intermediate System –Intermediate System (IS-IS) with TE extensions Signaling: • Label Distribution Protocol (LDP) [RFC 3036] • Constraint based LDP (CR-LDP) [RFC 3212] • Extensions to Resource Reservation Protocol (RSVP) for LSP tunnels [RFC 3209] • Border Gateway Protocol (BGP) [RFC 3107]
MPLS references • Multiprotocol Label Switching Architecture, RFC 3031, Jan 2001 • Requirements for traffic engineering over MPLS, RFC 2702, Sept 1999 • Traffic engineering extensions to OSPF version 2, RFC 3630, September 2003 • Traffic Engineering Extensions to OSPF version 3, Internet Draft <draft-ietf-ospf-ospfv3-traffic-07>, April 2006 • IS-IS extensions for traffic engineering, RFC 3784, June 2004 • LDP specification, RFC 3036, Jan 2001 • Constraint-based LSP setup using LDP, RFC 3212, Jan 2002 • RSVP-TE: Extensions to RSVP for LSP tunnels, RFC 3209, Dec 2001 • Carrying label information in BGP-4, RFC 3107, May 2001
Generalized MultiProtocol Label Switching (GMPLS) • GMPLS is an enhanced version of the MPLS-concept. • GMPLS related work is coordinated by the IETF Common Control and Measurement Plane (ccamp) working group. • In data networks, MPLS covers both the control plane (label binding, label distribution, etc.) and the data plane (packet forwarding). • In circuit switched networks there is no packet forwarding. • Only MPLS control plane components are applicable to circuit switched networks. • GMPLS assumes IP-based routing and signaling protocols, and IP addresses. (IP-centric)
GMPLS (former MPlS) – mapping to OTN Main features applicable to OTN (Optical Transport Network) • MPLS control plane is implemented in each OXC • Constraint-based routing and signaling provide control plane for OXCs • to discover, distribute, and maintain relevant state information associated with the OTN • to establish and maintain OCh trails • Each OXC is considered an equivalent of a Label Switched Router (LSR) • Lightpaths (OCh trails) are considered similar to Label Switched Paths (LSPs) • Lambdas and switch ports are considered similar to labels
GMPLS – new set of LSP interfaces • Packet Switch Capable (PSC) interfaces: • Recognize packet boundaries and can forward data based on the content of the packet header (IP header, MPLS shim header). • Layer-2 Switch Capable (L2SC) interfaces: • Recognize frame/cell boundaries and can forward data based on the content of the frame/cell header (Ethernet MAC header, ATM VPI/VCI). • Time-Division Multiplex Capable (TDM) interfaces: • Forward data based on the data’s time slot in a repeating cycle (SDH/SONET, G.709 TDM, PDH). • Lambda Switch Capable (LSC) interfaces: • Forward data based on the wavelength on which the data is received (wavelength, waveband). • Fiber-Switch Capable (FSC) interfaces: • Forward data based on a position of the data in the real world physical spaces (port, fiber).
GMPLS control plane – functional components • Resource discovery and link management • The transaction that establishes, verifies, updates and maintains the LSR adjacencies and their port pair association for their transport (data) plane. • LSR level resource table: resource map that includes attributes, neighbor identifiers, and real-time operation states. • Routing • Topology information dissemination • Path selection • Signaling • LSP creation, modification, deletion, restoration, and exception handling
GMPLS – LSR level resource discovery and link management • Self resource awareness/discovery • As a result, the LSR resource table is populated with local ID, physical attributes, and logical constraints parameters • Neighbor discovery and port association • The process of discovering the status of local links to all neighbors by each LSR in the network, The up/down status of each link, link parameters, and the identity of the remote end of the link must be determined (periodical operation) [LMP]. • Resource verification and monitoring • Neighbor operation state detection and configuration verification (continuous operation). • Service negotiation/discovery • Covers all aspects related to service rules/policy negotiation between neighbors.
GMPLS - Routing • Topology information dissemination • Distribution of topology information through the network to form a consistent network level resource view among LSRs. • What type of information is required? • How is the information disseminated? • Triggering mechanisms for information update? • GMPLS assumes that an IP-based routing protocol is used for topology information dissemination. • GMPLS extensions have been defined for the TE extended versions of OSPF and IS-IS.
GMPLS – Routing cont. • Path selection • Usually a constraint-based computation process, resulting in an explicit route or source route. • Hop-by-hop routing is also possible. • Specific constraints on optical layer routing • Re-configurable (but blocking) network elements such as OADMs • Transmission impairments • Absence of wavelength conversion • Path diversity
GMPLS - IGP Extensions OSPF and IS-IS extensions to carry additional information: • switching capabilities of link (PSC, L2SC, TDM, LSC, FSC) • link encoding (e.g. SONET, SDH, GbE, etc.) • grouping of links that share same fate (SRLG) • protection capabilities of link • incoming and outgoing interface ID • CSPF extensions: • take into account new constraints (e.g. link encoding, multiplexing capabilities, etc.) • compute diverse paths • compute bi-directional paths
GMPLS - Signaling • GMPLS inherits all signaling functions from MPLS-TE: • LSP creation • LSP deletion • LSP modification • LSP exception handling • Additional GMPLS signaling protocol requirements: • Creation of bi-directional LSPs • Support of unnumbered links • Rapid failure notification • LSP fast restoration
GMPLS – signaling extensions • Generalized label request • Supports communication of characteristics required to support the LSP being requested, including LSP encoding, switching type, and LSP payload • LSP bandwidth encoding values, carried in a per protocol specific manner (e.g. in the CR-LDP Traffic Parameters TLV) • Generalized label • Extends the traditional label by allowing the representation of labels that identify time-slots, wavelengths, or space division multiplexed positions, or “anything that is sufficient to identify a traffic flow”. • Non-hierarchical label. • Support of waveband switching • A waveband represents a set of contiguous wavelengths that can be switched together to a new waveband. • Waveband label contains 3 fields: waveband ID, start label, end label. • Suggested label • Is used to provide a downstream node with the upstream node's label preference. • May reduce latency of LSP setup
GMPLS – signaling extensions cont. • Label set • Is used to limit the label choices of a downstream node to a set of acceptable labels. • Explicit label control • Ingress LSR may specify the label(s) to use on one, some or all of the explicitly routed links for the forward and/or reverse path. • Bi-directional symmetric LSP • A symmetric bi-directional LSP has the same traffic engineering requirements including fate sharing, protection and restoration, LSRs, and resource requirements in each direction. • Downstream and upstream data paths are established using a single set of signaling messages. • New Upstream Label Object/TLV • Rapid notification of failure and events • Acceptable Label Set for notification on label error • Expedited notification (RSVP-TE only) • Link protection • Protection Information Object/TLV indicates: • The desired link protection for each link of an LSP • Whether the LSP is a primary or secondary LSP
GMPLS – LSP Protection and restoration • So far, only intra-area, intra-layer P&R mechanisms for handling single failure scenarios are being discussed. • Protection schemes: • 1+1 link protection • 1:N or M:N link protection • Enhanced protection • 1+1 LSP protection • Restoration schemes: • End-to-end LSP restoration with re-provisioning • End-to-end LSP restoration with pre-signaled recovery bandwidth reservation and no label pre-selection • End-to-end LSP restoration with pre-signaled recovery bandwidth reservation and label pre-selection • Local LSP restoration
GMPLS extensions to the MPLS control plane – a summary • Support of devices that perform switching in the time, wavelength and space domain. • Use of label stacking and the resulting LSP interface hierarchy • The concept of link bundling • The new Link Management Protocol (LMP) for automatic link configuration and control • Computation of physically disjoint paths by use of Shared Risk Link Group (SRLG). • The establishment of bi-directional symmetric LSPs
PSC Cloud TDM Cloud LSC Cloud LSC Cloud TDM Cloud PSC Cloud FSC Cloud Fiber 1 Bundle Fiber n PSC TDM LSC Explicit Label LSPs Time-slot LSPs Time-slot LSPs Explicit Label LSPs l LSPs l LSPs Fiber LSPs (multiplex low-order LSPs) (demultiplex low-order LSPs) GMPLS - LSP hierarchy • Nesting LSPs enhances system scalability • LSPs always start and terminate on similar interface types • LSP interface hierarchy • Packet Switch Capable (PSC) Lowest • Layer 2 Switch Capable (L2SC) • Time Division Multiplexing Capable (TDM) • Lambda Switch Capable (LSC) • Fiber Switch Capable (FSC) Highest
Bundled Link 1 Bundled Link 2 GMPLS - Link Bundling • Allows multiple parallel links between nodes to be advertised as a single link into the IGP • Enhances IGP and traffic engineering scalability • Component links must have the same: • Link type • Traffic engineering metric • Set of resource classes (colors) • Link multiplex capability (packet, TDM, λ, port) • (Max bandwidth request) (bandwidth of a component link) • Admission control is applied on a per-component link basis
GMPLS references • Optical Network Service Requirements, Internet Draft <draft-ietf-ipo-carrier-requirements-05>, December 2002 • Generalized Multi-Protocol Label Switching (GMPLS) Architecture, RFC 3945, October 2004 • Generalized Multi-Protocol Label Switching (GMPLS) Signaling Functional Description, RFC 3471, January 2003 • Routing extensions in support of generalized MPLS, RFC 4202, October 2005 • LSP hierarchy with generalized MPLS TE, RFC 4206, October 2005 • Requirements for Generalized MPLS (GMPLS) Signaling Usage and Extensions for Automatically Switched Optical Network (ASON), RFC 4139, July 2005 • Requirements for Generalized MPLS (GMPLS) Routing for Automatically Switched Optical Network (ASON), RFC 4258, November 2005
GMPLS references cont. • OSPF extensions in support of generalized MPLS, RFC 4203, October 2005 • IS-IS extensions in support of generalized MPLS, RFC 4205, October 2005 • Generalized Multi-Protocol Label Switching (GMPLS) signaling – Constraint-based routed label distribution protocol (CR-LDP) extensions, RFC 3472, January 2003 • Generalized Multi-Protocol Label Switching (GMPLS) signaling Resource ReserVation Protocol-Traffic Engineering (RSVP-TE) extensions, RFC 3473, January 2003 • Link management protocol (LMP), RFC 4204, October 2005 • Impairments and other constraints on optical layer routing, RFC 4054, May 2005 • Shared risk link groups inference and processing, Internet Draft <draft-papadimitriou-ccamp-srlg-processing-02>, June 2003
GMPLS technology specific references • Framework for GMPLS-based control of SDH/SONET networks, RFC 4257, December 2005 • Generalized Multi-Protocol Label Switching (GMPLS) Extensions for Synchronous Optical Network (SONET) and Synchronous Digital Hierarchy (SDH) Control, RFC 3946, October 2004 • Generalized MPLS (GMPLS) signaling extensions for G.709 optical transport networks control, RFC 4328, January 2006 • Traffic engineering extensions to OSPF for Generalized MPLS control of Sonet/SDH networks, Internet Draft <draft-mannie-ccamp-gmpls-sonet-sdh-ospf-01>, February 2003 • Traffic engineering extensions to OSPF for Generalized MPLS control of G.709 optical transport networks, Internet Draft <draft-gasparini-ccamp-gmpls-g709-ospf-00>, November 2002
ITU-T Recommendations • G.8080 Architecture for the Automatic Switched Optical Network (ASON) (06/2006) • G.7712 Architecture and Specification of Data Communication Network (03/2003) • G.7713 Distributed Call and Connection Management (DCM) (05/2006) • G.7713.1 Distributed call and connection management (DCM) based on PNNI (03/2003) • G.7713.2 Distributed Call and Connection Management: Signaling mechanism using GMPLS RSVP-TE (03/2003) • G.7713.3 Distributed Call and Connection Management: Signaling mechanism using GMPLS CR-LDP (03/2003) • G.7714 Generalized automatic discovery for transport entities (08/2005) • G.7715 Architecture and Requirements for Routing in the Automatic Switched Optical Networks (06/2002) • G.7715.1 ASON routing architecture and requirements for link state protocols (02/2004)
Optical Internetworking Forum (OIF) Implementation agreements • User Network Interface (UNI) 1.0 Signaling Specification, October 2001 • User Network Interface (UNI) 1.0 Signaling Specification, Release 2: Common Part, February 2004 • RSVP Extensions for User Network Interface (UNI) 1.0 Signaling, Release 2, February 2004 • Intra-carrier E-NNI Signaling Specification, February 2004
Transport-MPLS (T-MPLS) • Standardized by ITU-T for application in transport part of network only. • Simplified MPLS: all features not necessary for connection-oriented applications are removed, i.e. less complex operation and more easily managed than MPLS. • Management principles are adopted from existing standards/practice, e.g. from SONET/SDH. • Supports - engineered point-to-point bi-directional LSPs, - end-to-end LSP protection, and - advanced OAM. • Goal is to provide reliable packet-based technology (MPLS) in a form that is aligned with circuit-based transport networking.
T-MPLS (2) Differences from MPLS: • Use of bi-directional LSPs traversing the same links and nodes. • No LSP merging option. (Multipoint-to-point is allowed in MPLS, as in IP). Not allowed in pure connection oriented network. • No Equal Cost Multiple Path (ECMP) option. Not needed in connection-oriented network. • No Penultimate Hop Popping (PHP) option. Label must be present in last node. • (See whitepaper by TPACK: ”Transport-MPLS A New Route to Carrier Ethernet” for overview – or standards).