Network Working Group S. Yasukawa Internet-Draft NTT Intended Status: Informational A. Farrel Expires: September 2007 Old Dog Consulting March 2007 An analysis of scaling issues in MPLS-TE backbone networks draft-yasukawa-mpls-scaling-analysis-02.txt Status of this Memo By submitting this Internet-Draft, each author represents that any applicable patent or other IPR claims of which he or she is aware have been or will be disclosed, and any of which he or she becomes aware will be disclosed, in accordance with Section 6 of BCP 79. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet-Drafts. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress." The list of current Internet-Drafts can be accessed at http://www.ietf.org/ietf/1id-abstracts.txt. The list of Internet-Draft Shadow Directories can be accessed at http://www.ietf.org/shadow.html. Abstract Traffic engineered Multiprotocol Label Switching (MPLS-TE) is deployed in providers' backbone networks. As providers plan to grow these networks, they need to discover whether existing protocols and implementations can support the network sizes that they are planning. This document presents an analysis of some of the scaling concerns for MPLS-TE backbone networks, and examines the value of two techniques for improving scaling. The intention is to motivate the development of appropriate deployment techniques and protocol extensions to enable the applicaiton of MPLS-TE in large networks. This document considers only scalability for point-to-point MPLS-TE. Point-to-multipoint MPLS-TE is for future study. Yasukawa and Farrel [Page 1] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 Contents 1. Introduction ................................................... 3 2. Network Topologies ............................................. 4 2.1 The Snowflake Network Topology ................................ 4 2.2 The Ladder Network Topology ................................... 6 2.3 Commercial Drivers for Selected Configurations ................ 7 2.4 Other Network Topologies ...................................... 8 3. Required Network Sizes ........................................ 10 4. Issues of Concern for Scaling ................................. 10 4.1 LSP State .................................................... 10 4.2 Processing Overhead .......................................... 11 4.3 RSVP-TE Implications ......................................... 11 4.4 Management ................................................... 12 4.5 Practical Numbers .... ....................................... 13 5. Scaling in Flat Networks ...................................... 13 5.1 Snowflake Networks ........................................... 13 5.2 Ladder Networks .............................................. 14 6. Scaling Snowflake Networks with Forwarding Adjacencies ........ 17 6.1 Two Layer Hierarchy .......................................... 17 6.1.1 Tuning the Network Topology to Suit the Two Layer Hierarchy. 18 6.2 Alternative Two Layer Hierarchy .............................. 19 6.3 Three Layer Hierarchy ........................................ 19 6.4 Issues with Hierarchical LSPs ................................ 20 7. Scaling Ladder Networks with Forwarding Adjacencies ........... 21 7.1 Two Layer Hierarchy .......................................... 21 7.2 Three Layer Hierarchy ........................................ 22 7.3 Issues with Hierarchical LSPs ................................ 23 8. Scaling Improvements Through Multipoint-to-Point LSPs ......... 23 8.1 Overview of MP2P LSPs ........................................ 24 8.2 Scaling Improvements for Snowflake Networks .................. 24 8.2.1 Comparison with Other Scenarios ............................ 26 8.3 Scaling Improvements for Ladder Networks ..................... 27 8.3.1 Comparison with Other Scenarios ............................ 28 8.4 Issues with MP2P LSPs ........................................ 29 9. Combined Models ............................................... 30 10. Management Considerations .................................... 30 11. Security Considerations ...................................... 30 12. Recommendations .............................................. 31 13. IANA Considerations .......................................... 31 14. Acknowledgements ............................................. 31 15. Intellectual Property Consideration .......................... 31 16. Normative References ......................................... 32 17. Informative References ....................................... 32 18. Authors' Addresses ........................................... 33 19. Disclaimer of Validity ....................................... 33 20. Full Copyright Statement ..................................... 33 Yasukawa and Farrel [Page 2] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 1. Introduction As traffic engineered Multiprotocol Label Switching (MPLS-TE) grows in popularity, providers are looking at how they could deploy it in networks that are larger than those that have been seen so far. This is leading them to examine the number of label switched paths (LSPs) that may need to be supported at various points within the network, and to look at the consequent impact on control plane and management plane resources as well as on the constraints placed by the physical limitations of the routers in the network. Physical topology scaling concerns are addressed by building networks that are not fully meshed. Network topologies tend to be meshed in the core, but tree-shaped at the edges giving rise to a snow-flake design. Alternatively, the core may be more of a ladder shape with tree-shaped edges. MPLS-TE, however, establishes a logical full mesh between all edge points in the network, and this is where the scaling problems arise since the structure of the network tends to focus a large number of LSPs within the core of the network. This document presents two generic network topologies: the snow-flake and the ladder, and attmepts to parameterize the networks by making some generalities. It introduces terminology for the different scaling parameters and examines how many LSPs might be required to be carried within the core of a network. Two techniques (hierarchical and multipoint-to-point LSPs) are introduced and an examination is made of the scaling benefits that they offer as well as of some of the concerns with using these techniques. Of necessity, this document makes very many generalizations. Not least among these are a set of assumptions about the symmetry and connectedness of the physical network. It is hoped that these generalizations will not impinge on the usefulness of the overview of the scaling properties that this document attmepts to give. In deed, the symmetry of the example topologies tends to high-light the scaling issues of the different solution models, and this may be useful in exposing the worst case scenarios. Although protection mechanisms like Fast Re-route (FRR) [RFC4090] are briefly discussed, the main body of this document considers stable network cases. It should be noted that make-before-break re-optimisation after link failure may result in a significant number of 'duplicate' LSPs. This issue is not addressed in this document. It should also be understood that certain deployment models where separate traffic engineered LSPs are used to provide different Yasukawa and Farrel [Page 3] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 services such as layer 3 VPNs [RFC4110] or pseudowires [RFC3985], or different classes of service [RFC3270], may result in 'duplicate' or 'parallel' LSPs running between any pair of provider edge nodes (PEs). This scaling factor is also not considered in this document, but may be easily applied as a linear factor by the reader. The intention of this document is to help service providers discover whether existing protocols and implementations can support the network sizes that they are planning. To do this, it presents an analysis of some of the scaling concerns for MPLS-TE backbone networks, and examines the value of two techniques for improving scaling. This should motivate the development of appropriate deployment techniques and protocol extensions to enable the applicaiton of MPLS-TE in large networks. This document considers only scalability for point-to-point MPLS-TE. Point-to-multipoint MPLS-TE is for future study. 2. Network Topologies This document explores two network topology models. The first is the snowflake model where only the very core of the network is meshed, and the edges of the network are formed as trees rooted in the core. The second network topology considered is the ladder model where the core of the network is shaped and meshed in the form of a ladder and trees are attached rooted to the edge of the ladder. The sections that follow examine these topologies in detail in order to parameterize them. 2.1 The Snowflake Network Topology The snowflake toplogies considered in this document are based on a hierarchy of connectivity within the core network. PE nodes have connectivity to P-nodes as shown in Figure 1. There is no direct connectivity between the PEs. Dual homing of PEs to multiple P nodes is not considered in this document although it may be a valuable addition to a network configuration. P /|\ / | \ / | \ / | \ PE PE PE Figure 1 : PE to P Node Connectivity The relationship between P-nodes is also structured in a hierarchical way. Thus, as shown in Figure 2, multiple P-nodes at one level are Yasukawa and Farrel [Page 4] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 connected to a P-node at a higher level. We number the levels such that level 1 is the top level and level (n) is immediately above level (n+1), and we denote a P-node at level n as a P(n). As with PEs, there is no direct connectivity between P(n+1) nodes. Again, dual homing of P(n+1) nodes to multiple P(n) nodes is not considered in this document although it may be a valuable addition to a network configuration. P(n) /|\ / | \ / | \ / | \ P(n+1) P(n+1) P(n+1) Figure 2 : Relationship Between P-Nodes At the top level, P(1) nodes are connected in a full mesh. In reality, the level 1 part of the network may be slightly less well connected than this, but assuming a full mesh provides for generality. The key multipliers for scalability are the number of P(1) nodes, and the multiplier relationship between P(n) and P(n+1) at each level including down to PEs. We define the multiplier M(n) as the number of P(n+1) nodes at level (n+1) attached to any one P(n). We define S(n) as the number of nodes at level (n). Thus: S(n) = S(1)*M(1)*M(2)*...*M(n-1) So the number of PEs can be expressed as: S(PE) = S(1)*M(1)*M(2)*...*M(n) where the network has (n) layers of P-nodes. Thus we may depict an example snowflake network as shown in Figure 3. In this case: S(1) = 3 M(1) = 3 S(2) = S(1)*M(1) = 9 M(2) = 2 S(PE) = S(1)*M(1)*M(2) = 18 Yasukawa and Farrel [Page 5] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 PE PE PE PE PE PE \ \/ \/ / PE--P(2) P(2) P(2) P(2)--PE \ | | / \| |/ PE--P(2)---P(1)------P(1)---P(2)--PE / \ / \ PE \ / PE \/ P(1) /|\ / | \ / | \ PE--P(2) P(2) P(2)--PE / /\ \ PE PE PE PE Figure 3 : An Example Snowflake Network 2.2 The Ladder Network Topology The ladder networks considdered in this network are based on an arrangement of routers in the core network that resembles a ladder. Ladder networks typically have long and thin cores that are arranged as conventional ladders. That is, they have one or more spars connected by rungs. Each node on a spar may have: - connection to one or more other spars - conneciton to a tree of other core nodes - connection to customer nodes. Figure 4 shows a simplified example of a ladder network. A core of twelve nodes make up two spars connected by six rungs. Two of the nodes on the spars are themsleves PEs, while the rest have PEs subtended. PE PE PE PE PE PE PE | PE | PE PE | PE | PE \| \|/ |/ \| \|/ PE-P-----P-----P-----PE-----P-----P--PE | | | | | |\ | | | | | | PE | | | | | | PE-P-----P-----P-----P------P-----PE /| /|\ |\ |\ |\ PE PE PE | PE | PE | PE | PE PE PE PE PE Figure 4 : A Simplified Ladder Network. Yasukawa and Farrel [Page 6] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 In practice, not all nodes on a spar (call them Spar-Nodes) need to have subtended PEs or CEs. That is, they can exist simply to give connectivity along the spar to other spar nodes, or across a rung to another spar. Similarly, the connectivity between spars can be more complex with multiple connections from one spar-node to another spar. Lastly, the network may be complicated by the inclusion of more than two spars (or simplified by reduction to a single spar). These variables make the ladder network non-trivial to model. For the sake of simplicity we will make the following restrictions: - There are precisely two spars in the core network. - Every spar-node connects to precisely one spar-node on the other spar. That is, each spar-node is attached to precisely one rung. - Each spar-node connects to either one (end-spar) or two (core-spar) other spar-nodes on the same spar. - Every spar-node has the same number of PEs subtended. This does not mean that there are no P-nodes subtended to the spar-nodes, but does mean that the edge tree subtended to each spar-node is identical. From these restrictions we are able to quantify a ladder network as follows: R - The number of rungs. That is, the number of spar-nodes on each spar. S(1) - The number of spar-nodes in the network. S(1)=2*R. E - The number of subtended edge nodes (PEs) to each spar-node. The number of rungs may vary considerably. A number less than 3 is unlikely, and a number greater than 100 seems improbable. E can be treated as for the snowflake network. That is, we can consider a number of levels of attachment from P(1) nodes which are the spar-nodes, through P(i) down to P(n) which are the PEs. Practically, we need to only consider n=2 (PEs attached direct to the spar-nodes) and n=3 (one level of P-nodes between the PEs and the spar-nodes). Let M(i) be the ratio of P(i) nodes to P(i-1) nodes, i.e. the connectivity between levels of P-node as defined for the snowflake topology. Hence, the number of nodes at any level (n) is: S(n) = S(1)*M(1)*M(2)*...*M(n-1) Yasukawa and Farrel [Page 7] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 So number of PEs subtended to a spar node is: E = M(1)*M(2)*...*M(n) And the number of PEs can be expressed as: S(PE) = S(1)*M(1)*M(2)*...*M(n) = S(1)*E Thus we may depict an example ladder network as shown in Figure 5. In this case: R = 5 S(1) = 10 M(1) = 2 S(2) = S(1)*M(1) = 20 M(2) = 2 E = M(1)*M(2) = 4 S(PE) = S(1)*E = 40 PE PE PE PE PE PE PE PE PE PE PE PE PE PE PE PE \| \| \| \| |/ |/ |/ |/ P(2) P(2) P(2) P(2) P(2) P(2) P(2) P(2) \ \ | \ / | / / PE \ \ | \ / | / / PE \ \ \| \/ |/ / / PE-P(2)---P(1)---P(1)---P(1)---P(1)---P(1)---P(2)-PE | | | | | | | | | | | | | | | PE-P(2)---P(1)---P(1)---P(1)---P(1)---P(1)---P(2)-PE / / / | /\ |\ \ \ PE / / | / \ | \ \ PE / / | / \ | \ \ P(2) P(2) P(2) P(2) P(2) P(2) P(2) P(2) /| /| /| /| |\ |\ |\ |\ PE PE PE PE PE PE PE PE PE PE PE PE PE PE PE PE Figure 5 : An Example Ladder Network 2.3 Commercial Drivers for Selected Configurations It is reasonable to ask why these two particular network topologies have been chosen. The consideration must be physical scalability. Each node (label switching router - LSR) is only able to support a limited number of physical interfaces. This necessarily reduces the ability to fully mesh a network and leads to the tree-like structure of the network toward the PEs. Yasukawa and Farrel [Page 8] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 A realistic commercial consideration for an operator is the fact that the only revenue-generating nodes in the network are the PEs. Other nodes are needed only to support connectivity and scalability. Therefore, there is a desire to maximize S(PE) while minimizing the sum of S(n) for all values of (n). This could be achieved by minimizing the number of levels, and by maximizing the connectivity at each layer, M(n). Ultimately, however, this would produce a network of just interconnected PEs, which is clearly in conflict with the physical scaling situation. Therefore, the solution calls for a "few" levels with "relatively large" connectivity at each level. We might say that the cost-effectiveness of the network can be stated as: K = S(PE)/(S(1)+S(2) + ... + S(n)) where n is the level above the PEs We should observe, however, that this equation may be naive in that the cost of a network is not actually a function of the number of routers (since a router chasis is often free or low cost), but is really a function of the cost of the line cards which is, itself, a product of the capacity of the line cards. Thus, the relatively high connectivity decreases the cost-effectiveness, while a topology that tends to channel data through a network core tends to demand higher capacity (so more expensive) line cards. A further consideration is the availability of connectivity (usually fibers) between LSR sites. Although it is always possible to lay new fiber, this may not be cost-effective or timely. As much of a problem is likely to be the physical topology of the country in which the network is laid. If the country is 'long and thin' then a ladder network is likely to be used. This document examines the implications for control plane and data plane scalability of this type of network when MPLS-TE LSPs are used to provide full connectivity between all PEs. 2.4 Other Network Topologies As explained in Section 1, this document is using a two symmetrical and generalized network topologies for simplicity of modelling. In practice there are two other topological considerations. a. Multihoming It is relatively common for a node at level (n) to be attached to more than one node at level (n-1). This is particularly common at PEs that may be connected to more than one P(n). b. Meshing within a level A level in the network will often include links between P-nodes at the same level. This may result in a network that looks like a Yasukawa and Farrel [Page 9] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 series of concentric circles with spokes. Both of these features is likely to have some impact on the scaling of the network. However, for the purposes of establishing the ground- rules for scaling, this document restricts itself to the consideration of the symmetrical network described in Sections 2.1 and 2.2. Discussion of other network formats may be introduced in a future revision of this document. 3. Required Network Sizes An important question for this evaluation and analysis is the size of the network that operators require. How many PEs are required? What ratio of P to PE is acceptable. How many ports do devices have for physical connectivity? What type of MPLS-TE connectivity between PEs is required? Although presentation of figures for desired network sizes is ultimately pointless because history shows that networks grow beyond all projections, it is useful to set some acceptable lower bounds. That is, we can state that we already know that networks will be at least of a certain size. The most important features are: - The network should have at least 1000 PEs. - Each pair of PEs should be connected by at least one LSP in each direction. 4. Issues of Concern for Scaling This section presents some of the issues associated with the support of LSPs at an LSR or within the network that may mean that there is a a limit to the number LSPs that can be supported. 4.1 LSP State LSP state is the data (information) that must be stored at an LSR in order to maintain an LSP. Here we refer to the information that is necessary to maintain forwarding plane state and the additional information required when LSPs are established through control plane protocols. While the size of the LSP state is implementation-dependent, it is clear that any implementation will require some data in order to maintain LSP state. Thus LSP state becomes a scaling concern because as the number of LSPs at an LSR increases, so the amount of memory required to maintain the LSPs increases in direct proportion. Since the memory capacity of an LSR is limited, there is a related limit placed on the number LSPs that can be supported. Yasukawa and Farrel [Page 10] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 Note that techniques to reduce the memory requirements (such as data compression) may serve to increase the number of LSPs that can be supported, but this will only achieve a moderate multiplier and may significantly decrease the ability to process the state rapidly. 4.2 Processing Overhead Depending largely on implementation issues, the number of LSPs supported by an LSR may impact the processing speed for each LSP. For example, control block search times can increase with the number of control blocks, and even excellent implementations cannot completely mitigate this fact. Thus, since CPU power is constrained in any LSR, there may be a practical limit to the number of LSPs that can be supported. Further processing overhead considerations depend on issues specific to the control plane protocols, and are discussed in the next section. 4.3 RSVP-TE Implications Like many connection-oriented signaling protocols, RSVP-TE requires that state is held within the network in order to maintain LSPs. The impact of this is described in section 4.1. Note that RSVP-TE requires that separate information is maintained for upstream and downstream relationships, but does not require any specific implementation of that state. RSVP-TE is a soft-state protocol which means that protocol messages (refresh messages) must be regularly exchanged between signaling neighbors in order to maintain the state for each LSP that runs between the neighbors. A common period for the transmission (and receipt) of refresh messages is 30 seconds meaning that each LSR must send and receive one message in each direction (upstream and downstream) for every LSP it supports every 30 seconds. This has the potential to be a significant constraint on the scaling of the network, but various improvements [RFC2961] mean that this refresh processing can be significantly reduced allowing an implementation to be optimized to nearly remove all concerns about soft state scaling in a stable network. Observations of existing implementations indicate that there may be a threshold of around 50,000 LSPs above which an LSR struggles to achieve sufficient processing to maintain LSP state. Although refresh reduction [RFC2961] may substantially improve this situation, it has also been observed that under these circumstances the size of the Srefresh may become very large and the processing required may still cause significant disruption to an LSR. An alternative approach is to increase the refresh time. There is a Yasukawa and Farrel [Page 11] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 linear relationship between the percentage increase in refresh time and the improvement in performance for the LSR. However, it should be noted that RSVP-TE's soft-state nature depends on regular refresh messages, thus a degree of functionality is lost by increasing the refresh time. This loss may be partially mitigated by the use of the RSVP-TE Hello message, and can also be reduced by the use of various GMPLS extensions [RFC3473] such as the use of [RFC2961] message acknowledgements on all messages. RSVP-TE also requires that signaling adjacencies are maintained through the use of Hello message exchanges. Although [RFC3209] suggests that Hello messages should be retransmitted every 5ms, in practice values of around 3 seconds are more common. Nevertheless, the support of Hello messages can represent a scaling limitation on an RSVP-TE implementation since one message must be sent and received to/from each signaling adjacency every time period. This can impose limits on the number of neighbors (physical or logical) that an LSR supports. 4.4 Management Another practical concern for the scalability of large MPLS-TE networks is the ability to manage the network. This may be constrained by the available tools, the practicality of managing large numbers of LSPs, and the management protocols in use. Management tools are software implementations. Although such implementations should not constrain the control plane protocols, it is realistic to appreciate that network deployments will be limited by the scalability of the available tools. In practice, most existing tools have a limit to the number of LSPs that they can support. While an NMS may be able to support a large number of LSPs, the number that can be supported by an EMS (or the number supported by an NMS per-LSR) is more likely to be limited. Similarly, practical constraints may be imposed by the operation of management protocols. For example, an LSR may be swamped by management protocol requests to read information about the LSPs that it supports, and this might impact its ability to sustain those LSPs in the control plane. OAM, alarms, and notifications can further add to the burden placed on an LSR and limit the number of LSPs it can support. All of these consideration encourage a reduction in the number of LSPs supported within the network and at any particular LSR. Yasukawa and Farrel [Page 12] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 4.5 Practical Numbers In practice, reasonable target numbers are as follows. S(PE) >= 1000 Number of levels is 3. That is: 1, 2 and PE. M(2) <= 20 M(1) <= 20 S(1) <= 100 5. Scaling in Flat Networks Before proceeding to examine potential scaling improvements, we need to examine how well the flat networks described in the previous sections scale. Consider the requirement for a full mesh of LSPs linking all PEs. That is, each PE has an LSP to and from each other LSP. Thus, if there are S(PE) PEs in the network, there are S(PE)*(S(PE) - 1) LSPs. Define L(n) as the number of LSPs handled by a level (n) LSR. L(PE) = 2*(S(PE) - 1) 5.1 Snowflake Networks In a snowflake network (see Figure 3), L(2) can be computed as the sum of all LSPs for all attached PEs including the LSPs between the attached PEs (but being careful to only count those LSPs once). Thus, since the number of attached PEs is M(2), we have: L(2) = 2*M(2)*(S(PE) - 1) - M(2)*(M(2) - 1) L(1) can be computed as the sum of the number of LSPs for all downstream PEs less those that can be served exclusively by the attached P(2) nodes, and only counting the LSPs routed through two attached P(2) nodes once. So: L(1) = 2*M(1)*M(2)*(S(PE) - 1) - 2*M(1)*M(2) - M(2)*(M(1) - 1) = 2*M(1)*M(2)*[S(PE) - 2.5] + M(2) So, for example, with S(1) = 5, M(1) = 10, and M(2) = 20, we see: S(PE) = 1000 L(PE) = 1998 L(2) = 39580 L(1) = 399020 Yasukawa and Farrel [Page 13] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 Alternatively, with S(1) = 10, M(1) = 10, and M(2) = 20, we see: S(PE) = 2000 L(PE) = 3998 L(2) = 79580 L(1) = 799020 In both examples, the number of LSPs at the core (P(1)) nodes is probably unacceptably large even though there are only a relatively modest number of PEs. In fact, L(2) may even be too large in the second example. 5.2 Ladder Networks In ladder networks L(PE) remains the same at 2*(S(PE) - 1). L(2) can be computed using the same mechanism as for the snowflake topology because the subtended tree is the same format. Hence, L(2) = 2*M(2)*(S(PE) - 1) - M(2)*(M(2) - 1) But L(1) requires a different computation because each P(1) not only sees LSPs for the subtended PEs, but is also a transit node for some of the LSPs that cross the core (the core is not fully meshed). Each P(1) sees: o all of the LSPs between locally attached PEs o less the those LSPs between locally attached PEs that can be served exclusively by the attached P(2) nodes o all LSPs between locally attached PEs and remote PEs o LSPs in transit that pass through the P(1). The first three numbers are easily determined and match what we have seen from the snowflake network. They are: o E*(E-1) o M(1)*M(2)*(M(2)-1) = E*(M(2) - 1) o 2*E*E*(S(1) - 1) The number of LSPs in transit is more complicated to compute. It is simplified by not considering the ends of the ladders, but examining an arbitrary segment of the middle of the ladder such as shown in Figure 6. We look to compute and generalize the number of LSPs traversing each core link (labelled a and b in Figure 6) and so determine the number of transit LSPs seen by each P(1). Yasukawa and Farrel [Page 14] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 : : : : : : : : : : : : P(2) P(2) P(2) P(2) P(2) P(2) \ | \ / | / \ | \ / | / \| \/ |/ ......P(1)---P(1)---P(1)...... | a | | | |b | | | | ......P(1)---P(1)---P(1)...... /| /\ |\ / | / \ | \ / | / \ | \ P(2) P(2) P(2) P(2) P(2) P(2) : : : : : : : : : : : : Figure 6 : An Arbitrary Section of a Ladder Network Of course, the number of LSPs carried on links a and b in the Figure depends on how LSPs are routed through the core network. But if we assume a symmetrical routing policy and an even distribution of LSPs across all shortest paths, the result is the same. Now we can see that each P(1) sees half of 2a+b LSPs (since each LSP would otherwise be counted twice as it passed through the P(1)) except that some of the LSPs are locally terminated so are only included once in the sum 2a+b. So L(1) = a + b/2 - (locally terminated transit LSPs)/2 + (locally contained LSPs) Thus: L(1) = a + b/2 - 2*E*E*(S(1) - 1)/2 + E*(E-1) - E*(M(2) - 1) = a + b/2 + E*E*(2 - S(1)) - E*M(2) So all we have to do is work out a and b. Recall that the ladder length R = S(1)/2, and define X = E*E. Consider the contribution made by all of the LSPs that make n hops on the ladder to each of a and b. If the ladder was unbounded then we could say that in the case of a, there are n*2X LSPs along the spar only, and n(n-1)*2X/n = 2X(n-1) LSPs use a rung and the spar. Thus, Yasukawa and Farrel [Page 15] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 the LSPs that make n hops on the ladder contribute (4n-2)X LSPs to a; the edge cases are special because LSPs that make only one hop on the ladder cannot transit a P(1) but only start or end there. So with a ladder of length R = S(1)/2 we could say: R a = SUM[(4i-2)*X] + 2RX i=2 = 2*X*R*(R+1) And similarly, considering b in an unbounded ladder, the LSPs that only travel one hop on the LSP are a special case, contributing 2X LSPs, and each other LSP that traverses n hops on the ladder contributes 2n*2X/n = 4X LSPs. So: R+1 b = 2X + SUM[4X] i=2 = 2*X + 4*X*R In fact the ladders are bounded and so the number of LSPs is reduced because of the effect of the ends of the ladders. The links that see the most LSPs are in the middle of the ladder, and here we see that the formula for the contribution to the count of spar-only LSPs for a is only valid up to n=R/2, and for spar-and-rung LSPs for n=1+R/2. Above these limits the contribution made by spar-only LSPs decays as (n-R/2)*2X. However, for a first order approximation, we will use the values of a and b as computed above. This gives us: L(1) = a + b/2 + E*E*(2 - S(1)) - E*M(2) = 2*X*R*(R+1) + X + 2*X*R + E*E*(2 - S(1)) - E*M(2) = E*E*S(1)*(1 + S(1)/2) + E*E + E*E*S(1) + 2*E+E - E*E*S(1) - E*M(2) = E*E*S(1)*(1 + S(1)/2) + 3*E+E - E*M(2) = E*E*S(1)*S(1)/2 + E*E*S(1) + 3*E*E - E*M(2) So, for example, with S(1) = 6, M(1) = 10, and M(2) = 17, we see: E = 170 S(PE) = 1020 L(PE) = 2038 L(2) = 34374 L(1) = 777410 Yasukawa and Farrel [Page 16] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 Alternatively, with S(1) = 10, M(1) = 10, and M(2) = 20, we see: E = 200 S(PE) = 2000 L(PE) = 3998 L(2) = 79580 L(1) = 2516000 In both examples, the number of LSPs at the core (P(1)) nodes is probably unacceptably large even though there are only a relatively modest number of PEs. In fact, L(2) may even be too large in the second example. Compare the L(1) values with the total number of LSPs in the sytem S(PE)*(S(PE) - 1) which is 1039380 and 3998000 respectively. 6. Scaling Snowflake Networks with Forwarding Adjacencies One of the purposes of LSP hierarchies [RFC4206] is to improve the scaling properties of MPLS-TE networks. LSP tunnels (sometimes known as Forwarding Adjacencies (FAs)) may be established to provide connectivity over the core of the network and multiple edge-to-edge LSPs may be tunneled down a single FA LSP. In our network it is natural to consider a mesh of FA LSPs between all core nodes at the same level. We consider two possibilities here. In the first all P(2) nodes are connected to all other P(2) nodes, and the PE-to-PE LSPs are tunneled across the core of the network. In the second, an extra layer of hierarchy is introduced by connecting all P(1) nodes in a mesh and tunneling the P(2)-to-P(2) tunnels through these. 6.1 Two Layer Hierarchy In this hierarchy model, the P(2) nodes are connected by a mesh of tunnels. This means that the P(1) nodes do not see the PE-to-PE LSPs. It remains the case that: L(PE) = 2*(S(PE) - 1) L(2) is slightly increased. It can be computed as the sum of all LSPs for all attached PEs including the LSPs between the attached PE plus the number of FA LSPs providing a mesh to the other P(2) nodes. Thus, since the number of attached PEs is M(2) and the number of P(2) nodes is S(2), we have: L(2) = 2*M(2)*(S(PE) - 1) - M(2)*(M(2) - 1) + 2*(S(2) - 1) L(1), however, is significantly reduced and can be computed as the sum of the number of FA LSPs to and from each attached P(2) to each Yasukawa and Farrel [Page 17] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 other P(2) in the network, including (but counting only once) the FA LSPs between attached P(2) nodes. So: L(1) = 2*M(1)*(S(2) - 1) - M(1)*(M(1) - 1) So, for example, with S(1) = 5, M(1) = 10, and M(2) = 20, we see: S(PE) = 1000 S(2) = 50 L(PE) = 1998 L(2) = 39678 L(1) = 890 Alternatively, with S(1) = 10, M(1) = 10, and M(2) = 20, we see: S(PE) = 2000 S(2) = 100 L(PE) = 3998 L(2) = 79778 L(1) = 1890 So, in both examples, the problem of the number of LSPs at the core (P(1)) nodes is solved, but any problem with L(2) is made slightly worse. 6.1.1 Tuning the Network Topology to Suit the Two Layer Hierarchy Clearly we can reduce L(2) by selecting appropriate values of S(1), M(1) and M(2). We can do this pretty much with immunity since no change will affect L(PE), and since L(1) is now so small. Observe that: L(2) = 2*M(2)*(S(PE) - 1) - M(2)*(M(2) - 1) + 2*(S(2) - 1) where S(PE) = S(1)*M(1)*M(2) and S(2) = S(1)*M(1). So L(2) scales with M(2)^2 and we can have the most impact by reducing M(2). For example, with S(1) = 10, M(1) = 10, and M(2) = 10, we see: S(PE) = 1000 S(2) = 100 L(PE) = 1998 L(2) = 20088 L(1) = 1890 And similarly, with S(1) = 20, M(1) = 20, and M(2) = 5, we see: S(PE) = 2000 S(2) = 400 L(PE) = 3998 L(2) = 20768 L(1) = 15580 These considerable scaling benefits must be offset against the cost Yasukawa and Farrel [Page 18] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 effectiveness of the network. Recall that K = S(PE)/(S(1)+S(2) ... + S(n)) where n is the level above the PEs, so that for our network: K = S(PE) / (S(1) + S(2)) Thus, in the first example the cost-effectiveness has been halved from 1000/55 to 1000/110. And in the second example it has been reduced to roughly one quarter, changing from 2000/110 to 2000/420. So, although the tuning changes may be necessary to reach the desired network size, they come at a considerable cost to the operator. 6.2 Alternative Two Layer Hierarchy An alternative to the two layer hierarchy presented in section 6.1 is to provide a full mesh of FA LSPs between P(1) nodes. This technique is only of benefit to any nodes in the core of the level 1 network. Otherwise it makes no difference to the PE and P(2) nodes and increases the burden at the P(1) nodes since they have to support all of the PE-to-PE LSPs as in the flat model, plus the additional 2*(S(1) - 1) P(1)-to-P(1) FA LSPs. Thus, this approach should only be considered where there is a mesh of P-nodes wihtin the ring of P(1) nodes, and it is not considered further in this document. 6.3 Three Layer Hierarchy As demonstrated by section 6.2, introducing a mesh of FA LSPs at the top level (P(1)) has no benefit, but if we introduce an additional level in the network (P(3) between P(2) and PE) we can introduce a new layer of FA LSPs so that we have a full mesh of FA LSPs between all P(3) nodes to carry the PE-to-PE LSPs, and a full mesh of FA LSPs between all P(2) nodes to carry the P(3)-to-P(3) LSPs. The math starts to get a little less pretty! The number of PEs S(PE) = S(1)*M(1)*M(2)*M(3) and the number of PE-to-PE LSPs at a PE remains as L(PE) = 2*(S(PE) - 1). The number of LSPs at a P(3) can be deduced from section 6.1. It is the sum of all LSPs for all attached PEs including the LSPs between the attached PE plus the number of FA LSPs providing a mesh to the other P(3) nodes. L(3) = 2*M(3)*(S(PE) - 1) - M(3)*(M(3) - 1) + 2*(S(3) - 1) The number of LSPs at P(2) can also be deduced from section 6.1 since it is the sum of all LSPs for all attached P(3) nodes including the Yasukawa and Farrel [Page 19] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 LSPs between the attached PE plus the number of FA LSPs providing a mesh to the other P(2) nodes. L(2) = 2*M(2)*(S(3) - 1) - M(2)*(M(2) - 1) + 2*(S(2) - 1) Finally, L(1) can be copied straight from 6.1. L(1) = 2*M(1)*(S(2) - 1) - M(1)*(M(1) - 1) For example, with S(1) = 5, M(1) = 5, M(2) = 5, and M(3) = 8 we see: S(PE) = 1000 S(3) = 125 S(2) = 25 L(PE) = 1998 L(3) = 16176 L(2) = 1268 L(1) = 220 Similarly, with S(1) = 5, M(1) = 5, M(2) = 8, and M(3) = 10 we see: S(PE) = 2000 S(3) = 200 S(2) = 25 L(PE) = 3998 L(3) = 40038 L(2) = 3184 L(1) = 220 Of course, the extra level in the network tends to reduce the cost effectiveness of the networks with values of K = 1000/155 and K = 2000/230 (from 1000/55 and 2000/110) for the examples above. 6.4 Issues with Hierarchical LSPs A basic observation for hierarchical scaling techniques is that it is hard to have any impact on the number of LSPs that must be supported by the level of P(n) nodes adjacent to the PEs (for example, it is hard to reduce L(3) in section 6.3). In fact, the only way we can change the number of LSPs supported by these nodes is to change the scaling ratio M(n) in the network, in other words to change the number of PEs subtended to any P(n). But such a change has a direct effect on the number of PEs in the network and so the cost-effectiveness is impacted. Another concern with the hierarchical approach is that it must be configured and managed. This may not seem like a large burden, but it must be recalled that the P(n) nodes are not at the edge of the network - they are a set of nodes that must be identified so that the FA LSPs can be configured and provisioned. Effectively, the operator must plan and construct a layered network with a ring of P(n) nodes giving access to the level (n) network. This design activity is open Yasukawa and Farrel [Page 20] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 to considerable risk as failing to close the ring (i.e. allowing a node to be at both level (n+1) and at level (n)) may cause operational confusion. Protocol techniques (such as IGP auto-mesh [AUTO-MESH]) have been developed to reduce the configuration necessary to build this type of multi-level network. In the case of auto-mesh, the routing protocol is used to advertise the membership of a 'mesh group', and all members of the mesh can discover each other and connect with LSP tunnels. Thus the P(n) nodes giving access to level (n) can advertise their existence to each other, and it is not necessary to configure each with information about all of the others. Although this process can help to reduce the configuration overhead, it does not eliminate it as each member of the mesh group must still be planned and configured for membership. An important consideration for the use of hierarchical LSPs is how they can be protected using MPLS Fast Re-Route (FRR) [RFC4090]. FRR may provide link protection either by protecting the tunnels as they traverse a broken link, or by treating each level (n) tunnel LSP as a link in level (n+1), and providing protection for the level (n+1) LSPs (although in this model fault detection and propagation time may be an issue). Node protection may be performed in a similar way, but protection of the first and last nodes of a hierarchical LSP is particularly difficult. Additionally, the whole notion of scaling with regard to FRR gives rise to separate concerns that are outside the scope of this document as currently formulated. Finally, observe that we have been explaining these techniques using conveniently symmetrical networks. Consider how we would arrange the hierarchical LSPs in a network where some PEs are connected closer to the center of the network than others. 7. Scaling Ladder Networks with Forwarding Adjacencies 7.1 Two Layer Hierarchy The two layer hierarchy model can be use to place a tunnel between every pair of spar nodes. This has value (which it wouldn't have in the snowflake model, because the core P(1) nodes are not fully meshed. The number of LSPs seen by a P(1) node is then: o all of the tunnels terminating at the P(1) node o any transit tunnels o all of the LSPs due to subtended PEs. This is a substantial reduction because all of the transit LSPs are reduced to just one per remote P(1) that causes any transit LSP. So: Yasukawa and Farrel [Page 21] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 L(1) = 2*(S(1) - 1) + O(S(1)*S(1)/2) + 2*E*E*(S(1) - 1) + E*(E-1) - E*(M(2) - 1) where O(S(1)*S(1)/2) gives an upper bound order of magnitude. So: L(1) = S(1)*S(1)/2 + 2*S(1) + 2*E*E*(S(1) - 1) - E*M(2) - 2 So, in our two examples: With S(1) = 6, M(1) = 10, and M(2) = 17, we see: E = 170 S(PE) = 1020 L(PE) = 2038 L(2) = 34374 L(1) = 286138 Alternatively, with S(1) = 10, M(1) = 10, and M(2) = 20, we see: E = 200 S(PE) = 2000 L(PE) = 3998 L(2) = 79580 L(1) = 716060 Both of these show a excellent improvements over the previous L(1) figures of 777410 and 2516000. But the numbers are still too large to manage, and there is no improvement in the L(2) figures. 7.2 Three Layer Hierarchy We can also apply the three layer hierarchy to the ladder model. In this case the number of LSPs between P(1) nodes is not reduced, but tunnels are also set up between all P(2) nodes. Thus the number of LSPs seen by a P(1) node is: o all of the tunnels terminating at the P(1) node o any transit tunnels between P(1) nodes o all of the LSPs due to subtended P(2) nodes. No PE-to-PE LSPs are seen at the P(1) nodes. L(1) = 2*(S(1) - 1) + O(S(1)*S(1)/2) + 2*(S(1) - 1)*M(1)*M(1) + M(1)*(M(1) - 1) where O(S(1)*S(1)/2) gives an upper bound order of magnitude. So: L(1) = S(1)*S(1)/2 + 2*S(1) + 2*M(1)*M(1)*S(1) - M(1)(M(1) + 1) - 2 Unfortunately, there is a small increase in the number of LSPs seen Yasukawa and Farrel [Page 22] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 by the P(2) nodes. Each P(2) now sees all of the PE-to-PE LSPs that it saw before, and it is also an end point for a set of P(2)-to-P(2) tunnels. Thus L(2) increases to: L(2) = 2*M(2)*(S(PE) - 1) - M(2)*(M(2) - 1) + 2*(S(1)*M(1) - 1) So, in our two examples: With S(1) = 6, M(1) = 10, and M(2) = 17, we see: E = 170 S(PE) = 1020 L(PE) = 2038 L(2) = 34492 L(1) = 1118 Alternatively, with S(1) = 10, M(1) = 10, and M(2) = 20, we see: E = 200 S(PE) = 2000 L(PE) = 3998 L(2) = 79778 L(1) = 1958 This represents a very dramatic decrease in LSPs across the core. 7.3 Issues with Hierarchical LSPs The same issues exist for hierarchical LSPs as described in Section 6.4. Although dramatic improvements can be made to the scaling numbers for the number of LSPs at core nodes, this can only be done at the cost of configuring P(2) to P(2) tunnels. The mesh of P(1) tunnels is not enough. But the sheer number of P(2) to P(2) tunnels that must be configured is a management nightmare that can only be eased by using a technique like automesh [AUTO-MESH]. It is significant, however, that the scaling problem at the P(2) nodes cannot be improved by using tunnels, and the only solution to ease this in the hierarchical approach would be to institute another layer of hierarchy (that is, P(3) nodes) between the P(2) nodes and the PEs. This is, of course, a significant expense. 8. Scaling Improvements Through Multipoint-to-Point LSPs An alternative (or complementary) scaling technique has been proposed using multipoint-to-point (MP2P) LSPs. The fundamental improvement in this case is achieved by reducing the number of LSPs toward the destination as LSPs toward the same destination are merged. This section presents an overview of MP2P LSPs and describes their Yasukawa and Farrel [Page 23] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 applicability and scaling benefits. 8.1 Overview of MP2P LSPs Note that the MP2P LSPs discussed here are for MPLS-TE and are not the same concept familiar in the Label Distribution Protocol (LDP) described in [RFC3036]. Traffic flows generally converge toward their destination and this can be utilized by MPLS in constructing an MP2P LSP. With such an LSP, the LFIB mappings at each LSR are many-to-one so that multiple pairs {incoming interface, incoming label} are mapped to a single pair {outgoing interface, outgoing label}. Obviously, if per-platform labels are used, this mapping may be optimized within an implementation. It is important to note that with MP2P MPLS-TE LSPs the traffic flows are merged. That is, some additional form of identifier is required if demerging is required. For example, if the payload is IP traffic belonging to the same client network, no additional demerging information is required since the IP packet contains sufficient data. On the other hand, if the data comes, for example, from a variety of VPN client networks, then the flows will need to be labeled in their own right as point-to-point (P2P) flows, so that traffic can be disambiguated at the egress of the MP2P LSPs. Techniques for establishing MP2P MPLS-TE LSPs and for assigning the correct bandwidth downstream of LSP merge points are out of the scope of this document. 8.2 Scaling Improvements for Snowflake Networks Consider the network topology shown in figure 3. Suppose that we establish MP2P LSP tunnels such that there is one tunnel terminating at each PE, and that that tunnel has every other PE as an ingress. Thus, a PE-to-PE MP2P LSP tunnel would have S(PE)-1 ingresses and one egress, and there would be S(PE) such tunnels. Note that there still remain 2*(S(PE) - 1) PE-to-PE P2P LSPs that are carried through these tunnels. Let's consider the number of LSPs handled at each node in the network. The PEs continue to handle the same number of PE-to-PE P2P LSPs, and must also handle the MP2P LSPs. So: L(PE) = 2*(S(PE) - 1) + S(PE) But all P(n) nodes in the network only handle the MP2P LSP tunnels. Yasukawa and Farrel [Page 24] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 Nominally, this means that L(n) = S(PE) for all values of n, but life is not really that simple. The number of LSPs is no longer the only issue (although it may have some impact for some of the scaling concerns listed in section 4). We are now interested more directly in the amount of LSP state that is maintained by an LSR. We can quantify this according to the number of LSP segments managed by an LSR. So, in the case of a P2P LSP, an ingress or egress has one segment to maintain, while a transit has two segments. Similarly, for an MP2P LSP, an LSR must maintain one state for each upstream segment (which, we can assume, is in a one-to-one relationship with the number of upstream neighbors) and exactly one downstream segment - ingresses obviously have no upstream neighbors, and egresses have no downstream segments. So we can start again on our examination of the scaling properties, using X(n) to represent the amount of state held at each P(n). At the PEs, there is only connectivity to one other network node, the P(2) node. But note that if P2P LSPs need to be used to allow disambiguation of data at the MP2P LSP egresses, then these P2P LSPs are tunneled within the MP2P LSPs . So X(PE) is: X(PE) = 2*(S(PE) - 1) if no disambiguation is required and X(PE) = 4*(S(PE) - 1) if disambiguation is required Each P(2) node has M(2) downstream PEs to each of which a single MP2P LSP must be delivered coming from the one upstream P(1), and from which one LSP segment converges toward each other PE in the network. Note that not all MP2P LSPs initiated at subtended PEs are routed out through the parent P(1) since some terminate at local PEs. Thus: X(2) = 2*M(2) + M(2)*(S(PE) - 1) + S(PE) - M(2) = S(PE)*(M(2) + 1) Similarly, at each P(1) node there are M(1) downstream P(2) nodes and so a total of M(1)*M(2) downstream PEs. Each P(1) is connected in a full mesh with the other P(1) nodes so has (S(1) - 1) neighbors. So each P(1) must handle an LSP segment coming from each downstream P(2) headed to each non-downstream PE and an LSP segment to another P(1) for each non-downstream PE. At the same time, it must handle an LSP segment coming from each other P(1) headed to each downstream PE, and an LSP segment toward each downstream PE. Thus: X(1) = (M(1) + 1)*(S(PE) - M(1)*M(2)) + (S(1) - 1)*(S(PE) - M(1)*M(2)) + M(1)(M(2) = M(1)*(S(PE) + M(2)*(M(1) - S(1) + 1)) +S(1)*S(PE) Yasukawa and Farrel [Page 25] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 So, for example, with S(1) = 10, M(1) = 10, and M(2) = 10, we see: S(PE) = 1000 S(2) = 100 X(PE) = 3996 (or 1998) X(2) = 11000 X(1) = 20100 And similarly, with S(1) = 20, M(1) = 20, and M(2) = 5, we see: S(PE) = 2000 S(2) = 400 X(PE) = 5996 (or 2998) X(2) = 12000 X(1) = 80100 8.2.1 Comparison with Other Scenarios For comparison with the examples in sections 5 and 6, we need to convert those LSP-based figures to our new measure of LSP state. Observe that each LSP in sections 5 and 6 generates two state units at a transit LSR and one at an ingress or egress. So we can provide conversions as follows: Section 5 L(PE) = 2*(S(PE) - 1) L(2) = 2*M(2)*(S(PE) - 1) - M(2)*(M(2) - 1) L(1) = 2*M(1)*M(2)*[S(PE) - 2.5] - M(2) X(PE) = 2*(S(PE) - 1) X(2) = 4*M(2)*(S(PE) - 1) - 2*M(2)*(M(2) - 1) X(1) = 4*M(1)*M(2)*[S(PE) - 2.5] - 2*M(2) So that using the example figures in section 7.1 (S(1) = 10, M(1) = 10, and M(2) = 10) we see: X(PE) = 1998 X(2) = 39780 X(1) = 398980 Clearly this technique is a significant improvement over the flat network within the network, although the PEs are more heavily stressed. Section 6.1 L(PE) = 2*(S(PE) - 1) L(2) = 2*M(2)*(S(PE) - 1) - M(2)*(M(2) - 1) + 2*(S(2) - 1) L(1) = 2*M(1)*(S(2) - 1) - M(1)*(M(1) - 1) S(2) = S(1)*M(1) X(PE) = 2*(S(PE) - 1) X(2) = 4*M(2)*(S(PE) - 1) - 2*M(2)*(M(2) - 1) + 2*(S(2) - 1) X(1) = 4*M(1)*(S(2) - 1) - 2*M(1)*(M(1) - 1) Yasukawa and Farrel [Page 26] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 So that using the example figures in section 7.1 (S(1) = 10, M(1) = 10, and M(2) = 10) we see: X(PE) = 1998 X(2) = 39881 X(1) = 3780 And we can observe that the MP2P model is better at P(2), but the hierarchical model is better at P(1). In fact, this can be generalized to observe that the MP2P model produces best effects toward the edge of the network, while the hierarchical model makes most impression at the core. However, the requirement for P2P LSPs tunneled within the MP2P LSPs does cause a double burden at the PEs. 8.3 Scaling Improvements for Ladder Networks MP2P LSPs applied just within the ladder will not makea significant difference, but applying MP2P for all LSPs and at all nodes makes a very big difference without requiring any further configuration. LSP state at a spar node may be divided into those LSPs segments that enter or leave the spar node due to subtended PEs (local LSP segments), and those that enter or leave the spar node due to remote PEs (remote segments). The local segments may be counted as: o E LSPs targeting local PEs o (S(1)-1)*E*M(1) LSPs targeting remote PEs The remote segments may be counted as: o (S(1)-1)*E outgoing LSPs targeting remote PEs o <= 3*S(1)*E incoming LSPs targeting any PE (there are precisely P(1) nodes attached to any other P(1) node). Hence, treating L(1) as a measure of LSP state rather than a count of LSPs, we get: L(1) <= E + (S(1)-1)*E*M(1) + (S(1)-1)*E + 3*S(1)*E <= (4 + M(1))*S(1)*E - M(1)*E The number of LSPs at the P(2) nodes is also improved. We may also count the LSP state in the same way so that there are: o M(2) LSPs targeting local PEs o M(2)*(S(1)*E) LSPs from local PEs to all other PEs o S(1)*E - M(2) LSPs to remote PEs. Yasukawa and Farrel [Page 27] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 So treating L(2) as a measure of LSP state and not a count of LSPs, we have: L(2) = M(2) + M(2)*(S(1)*E) + S(1)*E - M(2) = (M(2) + 1)*S(1)*E Our examples from Section 5.2 give us the following numbers: With S(1) = 6, M(1) = 10, and M(2) = 17, we see: E = 170 S(PE) = 1020 L(PE) = 2038 L(2) = 18360 L(1) <= 12580 Alternatively, with S(1) = 10, M(1) = 10, and M(2) = 20, we see: E = 200 S(PE) = 2000 L(PE) = 3998 L(2) = 42000 L(1) <= 26000 8.3.1 Comparison with Other Scenarios The use of MP2P compares very favourably with all scaling scenarios. It is the only technique able to reduce the value of L(2), and it does this by a factor of almost two. The impact on L(1) is better than everything except the three level hierarcy. It should also be recalled that the numbers presented in Section 8.2 count the LSP state and not the number of LSPs, so there may be further benefits. The following table provides a quick cross-reference for the figures for the example ladder networks. Example| Count | Unmodified | 1-Level | 2-Level | MP2P | | | Hierarchy | Hierarchy | -------+-------+------------+------------+-------------+------- A | L(2) | 34374 | 34374 | 34492 | 18360 | L(1) | 777410 | 286138 | 1118 | 12580 -------+-------+------------+------------+-------------+------- B | L(2) | 79580 | 79580 | 79778 | 42000 | L(1) | 2516000 | 716060 | 1958 | 26000 Yasukawa and Farrel [Page 28] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 8.4 Issues with MP2P LSPs The biggest challenges for MP2P LSPs are the provision of support in the control and data planes. To some extent support must also be provided in the management plane. Control plane support is just a matter of defining the protocols and procedures [MP2P-RSVP], although it must be clearly understood that this will introduce some complexity to the control plane. Hardware issues may be a little more tricky. For example, the capacity of the upstream segments must never (allowing for statistical over-subscription) exceed the capacity of the downstream segment. Similarly, data planes must be equipped with sufficient buffers to handle incoming packet collisions. The management plane will be impacted in several ways. Firstly the management applications will need to handle LSPs with multiple senders. This means that, although the applications need to process fewer LSPs, they will be more complicated and will, in fact, need to process the same number of ingresses and egresses. Other issues like diagnostics and OAM would also need to be enhanced to support MP2P, but might be borrowed heavily from LDP networks. Lastly, note that when the MP2P solution is used, the receiver (the single egress PE of an MP2P tunnel) cannot use the incoming label as an indicator of the source of the data. Contrast this with P2P LSPs. Depending on deployment, this might not be an issue since the PE-PE connectivity may in any case be a tunnel with inner labels to discriminate the data flows. In other deployments, it may be considered necessary to include additional PE-PE P2P LSPs and tunnel these through the MP2P LSPs. This would require the PEs to support twice as many LSPs. Since PEs are not usually as fully specified as P-routers, this may cause some concern although the use of previous hop popping on the MP2P LSPs might help to reduce this issue. In all cases, care must be taken not to confuse the reduction in the number of LSPs with a reduction in the LSP state that is required. In fact, the discussion in Section 8.2 is slightly over-optimistic since LSP state toward the destination will probably need to include sender information and so will increase depending on the number of senders for the MP2P LSP. Section 8.3, on the other hand, counts LSP state rather than LSPs. This issue is clearly dependent on the protocol solution for MP2P RSVP-TE which is out of scope for this document. MPLS Fast Re-route (FRR) [RFC4090] is an attractive scheme for providing rapid local protection from node or link failures. Such a Yasukawa and Farrel [Page 29] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 scheme has, however, not been designed for MP2P at the time of writing, so it remains to be seen how practical it would be, especially in the case of the failure of a merge node. Initial examination of this case suggests that FRR would not be a problem for MP2P given that each flow can be handled separately. As a final note, observe that the MP2P scenario presented in this document may be optimistic. MP2P LSP merging may be hard to achieve between LSPs with significantly different traffic and QoS parameters. Therefore, it may be necessary to increase the number of MP2P LSPs arriving at an egress. 9. Combined Models There is nothing to prevent the combination of hierarchical and MP2P solutions within a network. Note that if MP2P LSPs are tunneled through P2P FA LSPs across the core, none of the benefit of LSP merging is seen for the hops during which the MP2P LSPs are tunneled. On the other hand, it is possible to construct solutions where MP2P FA LSPs are constructed within the network resulting in savings from both modes of operation. 10. Management Considerations The management issues of the two models presented in this document have been discussed in line. Neither solution is without its management overhead. Note, however, that scalability of management tools is one of the motivators for this work and that network scaling solutions that reduce the active management of LSPs at the cost of additional effort to manage the more static elements of the network represent a benefit. That is, it is worth the additional effort to set up MP2P or FA LSPs if it means that the network can be scaled to a larger size without being constrained by the management tools. 11. Security Considerations The techniques described in this document use existing or yet-to-be-defined signaling protocol extensions and are subject to the security provided by those extensions. Note that we are talking about tunneling techniques used within the network and both approaches are vulnerable to the creation of bogus tunnels that deliver data to an egress or consume network resources. The MP2P technique may prove harder to debug through OAM methods than Yasukawa and Farrel [Page 30] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 the FA LSP approach. 12. Recommendations At this stage, no recommendations are made, but it would be valuable to consult more widely to discover: - The concerns of other service providers with respect to network scalability. - More opinions on the realistic constraints to the network parameters listed in Section 4. - Desirable values for the cost-effectiveness of the network (parameter K) - The applicability, manageability and support for the two techniques described - The feasibility of combining the two techniques as discussed in Section 9. 13. IANA Considerations This document makes no requests for IANA action. 14. Acknowledgements The authors are grateful to Jean-Louis Le Roux for discussions and review input. Thanks to Ben Niven-Jenkins for his comments. 15. Intellectual Property Consideration The IETF takes no position regarding the validity or scope of any Intellectual Property Rights or other rights that might be claimed to pertain to the implementation or use of the technology described in this document or the extent to which any license under such rights might or might not be available; nor does it represent that it has made any independent effort to identify any such rights. Information on the procedures with respect to rights in RFC documents can be found in BCP 78 and BCP 79. Copies of IPR disclosures made to the IETF Secretariat and any assurances of licenses to be made available, or the result of an attempt made to obtain a general license or permission for the use of such proprietary rights by implementers or users of this specification can be obtained from the IETF on-line IPR repository at http://www.ietf.org/ipr. The IETF invites any interested party to bring to its attention any copyrights, patents or patent applications, or other proprietary rights that may cover technology that may be required to implement this standard. Please address the information to the IETF at ietf-ipr@ietf.org. Yasukawa and Farrel [Page 31] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 16. Normative References [RFC4206] Kompella, K. and Y. Rekhter, "Label Switched Paths (LSP) Hierarchy with Generalized Multi-Protocol Label Switching (GMPLS) Traffic Engineering (TE)", RFC 4206, October 2005. 17. Informative References [RFC2961] Berger, L., Gan, D., Swallow, G., Pan, P., Tommasi, F. and S. Molendini, "RSVP Refresh Overhead Reduction Extensions", RFC 2961, April 2001. [RFC3036] Andersson, L., Doolan, P., Feldman, N., Fredette, A. and B. Thomas, "LDP Specification", RFC 3036, January 2001. [RFC3209] Awduche, D., Berger, L., Gan, D., Li, T., Srinivasan, V. and G. Swallow, "RSVP-TE: Extensions to RSVP for LSP Tunnels", RFC 3209, December 2001. [RFC3270] Le Faucheur, F., et al., "Multi-Protocol Label Switching (MPLS) Support of Differentiated Services", RFC 3270, May 2002. [RFC3473] Berger, L., et al., Editor, "Generalized Multi- Protocol Label Switching (GMPLS) Signaling Resource ReserVation Protocol-Traffic Engineering (RSVP-TE) Extensions", RFC 3473, January 2003. [RFC3985] Bryant, S., and Pate, P., "Pseudo Wire Emulation Edge-to-Edge (PWE3) Architecture", RFC 3985, March 2005. [RFC4090] P. Pan, G. Swallow, A. Atlas (Editors), "Fast Reroute Extensions to RSVP-TE for LSP Tunnels", work in progress. [RFC4110] Callon, R., and Suzuki, M., "A Framework for Layer 3 Provider-Provisioned Virtual Private Networks (PPVPNs)", RFC 4110, July 2005. [AUTO-MESH] Vasseur, JP., and Le Roux, JL., "Routing extensions for discovery of Multiprotocol (MPLS) Label Switch Router (LSR) Traffic Engineering (TE) mesh membership", draft-ietf-ccamp-automesh, work in progress. Yasukawa and Farrel [Page 32] draft-yasukawa-mpls-scaling-analysis-02.txt March 2007 [MP2P-RSVP] Yasukawa, Y., "Supporting Multipoint-to-Point Label Switched Paths in Multiprotocol Label Switching Traffic Engineering", draft-yasukawa-mpls-mp2p-rsvpte, work in progress. 18. Authors' Addresses Seisho Yasukawa NTT Corporation 9-11, Midori-Cho 3-Chome Musashino-Shi, Tokyo 180-8585 Japan Phone: +81 422 59 4769 EMail: s.yasukawa@hco.ntt.co.jp Adrian Farrel Old Dog Consulting EMail: adrian@olddog.co.uk 19. Disclaimer of Validity This document and the information contained herein are provided on an "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY, THE IETF TRUST AND THE INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. 20. Full Copyright Statement Copyright (C) The IETF Trust (2007). This document is subject to the rights, licenses and restrictions contained in BCP 78, and except as set forth therein, the authors retain all their rights. Yasukawa and Farrel Expires September 2007 [Page 33]