Internet Engineering Task Force (IETF) A. Malis, Ed. Request for Comments: 7709 Huawei Technologies Category: Informational B. Wilson ISSN: 2070-1721 Applied Communication Sciences G. Clapp AT&T Labs Research V. Shukla Verizon Communications November 2015
Requirements for Very Fast Setup of GMPLS Label Switched Paths (LSPs)
Abstract
Establishment and control of Label Switch Paths (LSPs) have become mainstream tools of commercial and government network providers. One of the elements of further evolving such networks is scaling their performance in terms of LSP bandwidth and traffic loads, LSP intensity (e.g., rate of LSP creation, deletion, and modification), LSP set up delay, quality-of-service differentiation, and different levels of resilience.
The goal of this document is to present target scaling objectives and the related protocol requirements for Generalized Multi-Protocol Label Switching (GMPLS).
Status of This Memo
This document is not an Internet Standards Track specification; it is published for informational purposes.
This document is a product of the Internet Engineering Task Force (IETF). It represents the consensus of the IETF community. It has received public review and has been approved for publication by the Internet Engineering Steering Group (IESG). Not all documents approved by the IESG are a candidate for any level of Internet Standard; see Section 2 of RFC 5741.
Information about the current status of this document, any errata, and how to provide feedback on it may be obtained at http://www.rfc-editor.org/info/rfc7709.
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Copyright Notice
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This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License.
Generalized Multi-Protocol Label Switching (GMPLS) [RFC3471] [RFC3945] includes an architecture and a set of control-plane protocols that can be used to operate data networks ranging from packet-switch-capable networks, through those networks that use Time Division Multiplexing, to WDM networks. The Path Computation Element (PCE) architecture [RFC4655] defines functional components that can be used to compute and suggest appropriate paths in connection- oriented traffic-engineered networks. Additional wavelength switched optical networks (WSON) considerations were defined in [RFC6163].
This document refers to the same general framework and technologies, but it adds requirements related to expediting LSP setup under heavy connection churn scenarios, while achieving low blocking under an overall distributed control plane. This document focuses on a specific problem space -- high-capacity and highly dynamic connection request scenarios -- that may require clarification and or extensions to current GMPLS protocols and procedures. In particular, the purpose of this document is to address the potential need for protocols and procedures that enable expediting the setup of LSPs in high-churn scenarios. Both single-domain and multi-domain network scenarios are considered.
This document focuses on the following two topics: 1) the driving applications and main characteristics and requirements of this problem space, and 2) the key requirements that may be novel with respect to current GMPLS protocols.
This document presents the objectives and related requirements for GMPLS to provide the control for networks operating with such performance requirements. While specific deployment scenarios are considered part of the presentation of objectives, the stated requirements are aimed at ensuring the control protocols are not the limiting factor in achieving a particular network's performance. Implementation dependencies are out of scope of this document.
Other documents may be needed to define how GMPLS protocols meet the requirements laid out in this document. Such future documents may define extensions or simply clarify how existing mechanisms may be used to address the key requirements of highly dynamic networks.
The Defense Advanced Research Projects Agency (DARPA) Core Optical Networks (CORONET) program [Chiu] is an example target environment that includes IP and optical commercial and government networks, with a focus on highly dynamic and resilient multi-terabit core networks.
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It anticipates the need for rapid (sub-second) setup and SONET/SDH- like restoration times for high-churn (up to tens of requests per second network wide and holding times as short as one second) on- demand wavelength, sub-wavelength, and packet services for a variety of applications (e.g., grid computing, cloud computing, data visualization, fast data transfer, etc.). This must be done while meeting stringent call-blocking requirements and while minimizing the use of resources such as time slots, switch ports, wavelength conversion, etc.
The motivation for this document, and envisioned related future documents, is two-fold:
1. The anticipated need for rapid setup, while maintaining low blocking, of large bandwidth and highly churned on-demand connections (in the form of sub-wavelengths, e.g., OTN ODUx, and wavelengths, e.g., OTN OCh) for a variety of applications including grid computing, cloud computing, data visualization, and intra- and inter-datacenter communications.
2. The ability to set up circuit-like LSPs for large bandwidth flows with low setup delays provides an alternative to packet-based solutions implemented over static circuits that may require tying up more expensive and power-consuming resources (e.g., router ports). Reducing the LSP setup delay will reduce the minimum bandwidth threshold at which a GMPLS circuit approach is preferred over a layer 3 (e.g., IP) approach. Dynamic circuit and virtual circuit switching intrinsically provide guaranteed bandwidth, guaranteed low-latency and jitter, and faster restoration, all of which are very hard to provide in packet-only networks. Again, a key element in achieving these benefits is enabling the fastest possible circuit setup times.
Future applications are expected to require setup times that are as fast as 100 ms in highly dynamic, national-scale network environments while meeting stringent blocking requirements and minimizing the use of resources such as switch ports, wavelength converters/ regenerators, and other network design parameters. Of course, the benefits of low setup delay diminish for connections with long holding times. For some specific applications, a trade-off may be required, as the need for rapid setup may be more important than their requirements for other features currently provided in GMPLS (e.g., robustness against setup errors).
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With the advent of data centers, cloud computing, video, gaming, mobile and other broadband applications, it is anticipated that connection request rates may increase, even for connections with longer holding times, either during limited time periods (such as during the restoration from a data center failure) or over the longer term, to the point where the current GMPLS procedures of path computation/selection and resource allocation may not be timely, thus leading to increased blocking or increased resource cost. Thus, extensions of GMPLS signaling and routing protocols (e.g., OSPF-TE) may also be needed to address heavy churn of connection requests (i.e., high-connection-request arrival rate) in networks with high- traffic loads, even for connections with relatively longer holding times.
There are several emerging applications that fall under the problem space addressed here in several service areas such as provided by telecommunication carriers, government networks, enterprise networks, content providers, and cloud providers. Such applications include research and education networks / grid computing, and cloud computing. Detailing and standardizing protocols to address these applications will expedite the transition to commercial deployment.
In the target environment, there are multiple Bandwidth-on-Demand service requests per second, such as might arise as cloud services proliferate. It includes dynamic services with connection setup requirements that range from seconds to milliseconds. The aggregate traffic demand, which is composed of both packet (IP) and circuit (wavelength and sub-wavelength) services, represents a five to twenty-fold increase over today's traffic levels for the largest of any individual carrier. Thus, the aggressive requirements must be met with solutions that are scalable, cost effective, and power efficient, while providing the desired quality of service (QoS).
There are two key performance-scaling requirements in the target environment that are the main drivers behind this document:
1. Connection request rates ranging from a few requests per second for high-capacity (e.g., 40 Gb/s, 100 Gb/s) wavelength-based LSPs to around 100 requests per second for sub-wavelength LSPs (e.g., OTN ODU0, ODU1, and ODU2).
2. Connection setup delay of around 100 ms across a national or regional network. To meet this target, assuming pipelined cross- connection and worst-case propagation delay and hop count, it is
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estimated that the maximum processing delay per hop is around 700 microseconds [Lehmen]. Optimal path selection and resource allocation may require somewhat longer processing (up to 5 milliseconds) in either the destination or source nodes and possibly tighter processing delays (around 500 microseconds) in intermediate nodes.
The model for a national network is that of the continental US with up to 100 nodes and LSPs with distances up to ~3000 km and up to 15 hops.
A connection setup delay is defined here as the time between the arrival of a connection request at an ingress edge switch -- or more generally a Label Switch Router (LSR) -- and the time at which information can start flowing from that ingress switch over that connection. Note that this definition is more inclusive than the LSP setup time defined in [RFC5814] and [RFC6777], which do not include PCE path computation delays.
This section lists the protocol requirements for very fast setup of GMPLS LSPs in order to adequately support the service characteristics described in the previous sections. These requirements may be the basis for future documents, some of which may be simply informational, while others may describe specific GMPLS protocol extensions. While some of these requirements may have implications on implementations, the intent is for the requirements to apply to GMPLS protocols and their standardized mechanisms.
R1 The portion of the LSP establishment time related to protocol processing should scale linearly based on the number of traversed nodes.
R2 End-to-end LSP data path availability should be bounded by the worst-case single-node data path establishment time. In other words, pipelined cross-connect processing as discussed in [RFC6383] should be enabled.
R3 LSP establishment time shall depend on the number of nodes supporting an LSP and link propagation delays and not on any off (control) path transactions, e.g., PCC-PCE and PCC-PCC communications at the time of connection setup, even when PCE- based approaches are used.
R4 LSP holding times as short as one second must be supported.
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R5 The protocol aspects of LSP signaling must not preclude LSP request rates of tens per second.
R6 The above requirements should be met even when there are failures in connection establishment, i.e., LSPs should be established faster than when crank-back is used.
R7 These requirements are applicable even when an LSP crosses one or more administrative domains/boundaries.
R8 The above are additional requirements and do not replace existing requirements, e.g., alarm-free setup and teardown, recovery, or inter-domain confidentiality.
Being able to support very fast setup and a high-churn rate of GMPLS LSPs is not expected to adversely affect the underlying security issues associated with existing GMPLS signaling. If encryption that requires key exchange is intended to be used on the signaled LSPs, then this requirement needs to be included as a part of the protocol design process, as the usual extra round-trip time (RTT) for key exchange will have an effect on the setup and churn rate of the GMPLS LSPs. It is possible to amortize the costs of key exchange over multiple exchanges (if those occur between the same peers) so that some exchanges need not cost a full RTT and operate in so-called zero-RTT mode.
The authors would like to thank Ann Von Lehmen, Joe Gannett, Ron Skoog, and Haim Kobrinski of Applied Communication Sciences for their comments and assistance on this document. Lou Berger provided editorial comments on this document.
[RFC6163] Lee, Y., Ed., Bernstein, G., Ed., and W. Imajuku, "Framework for GMPLS and Path Computation Element (PCE) Control of Wavelength Switched Optical Networks (WSONs)", RFC 6163, DOI 10.17487/RFC6163, April 2011, <http://www.rfc-editor.org/info/rfc6163>.
[RFC6777] Sun, W., Ed., Zhang, G., Ed., Gao, J., Xie, G., and R. Papneja, "Label Switched Path (LSP) Data Path Delay Metrics in Generalized MPLS and MPLS Traffic Engineering (MPLS-TE) Networks", RFC 6777, DOI 10.17487/RFC6777, November 2012, <http://www.rfc-editor.org/info/rfc6777>.
[Chiu] Chiu, A., et al., "Architectures and Protocols for Capacity Efficient, Highly Dynamic and Highly Resilient Core Networks", Journal of Optical Communications and Networking vol. 4, No. 1, pp. 1-14, 2012, DOI 10.1364/JOCN.4.000001, <http://dx.doi.org/10.1364/JOCN.4.000001>.
[Lehmen] Von Lehmen, A., et al., "CORONET: Testbeds, Demonstration, and Lessons Learned", Journal of Optical Communications and Networking Vol. 7, Issue 3, pp. A447-A458, 2015, DOI 10.1364/JOCN.7.00A447, <http://dx.doi.org/10.1364/JOCN.7.00A447>.
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