rfc9706.original		rfc9706.txt
	MOPS L. Giuliano		Internet Engineering Task Force (IETF) L. Giuliano
	Internet-Draft Juniper Networks		Request for Comments: 9706 Juniper Networks
	Intended status: Informational C. Lenart		Category: Informational C. Lenart
	Expires: 22 February 2025 Verizon		ISSN: 2070-1721 Verizon
	R. Adam		R. Adam
	GEANT		GEANT
	21 August 2024		December 2024
	TreeDN- Tree-based CDNs for Live Streaming to Mass Audiences		TreeDN- Tree-based CDNs for Live Streaming to Mass Audiences
	draft-ietf-mops-treedn-07
	Abstract		Abstract
	As Internet audience sizes for high-interest live events reach		As Internet audience sizes for high-interest live events reach
	unprecedented levels and bitrates climb to support 4K/8K/Augmented		unprecedented levels and bitrates climb to support 4K/8K Augmented
	Reality (AR), live streaming can place a unique type of stress upon		Reality (AR), live streaming can place a unique type of stress upon
	network resources. TreeDN is a tree-based CDN architecture designed		network resources. TreeDN is a tree-based CDN architecture designed
	to address the distinctive scaling challenges of live streaming to		to address the distinctive scaling challenges of live streaming to
	mass audiences. TreeDN enables operators to offer Replication-as-		mass audiences. TreeDN enables operators to offer Replication-as-
	a-Service (RaaS) at a fraction the cost of traditional, unicast-based		a-Service (RaaS) at a fraction of the cost of traditional, unicast-
	CDNs- in some cases, at no additional cost to the infrastructure. In		based CDNs; in some cases, there is no additional cost to the
	addition to efficiently utilizing network resources to deliver		infrastructure. In addition to efficiently utilizing network
	existing multi-destination traffic, this architecture also enables		resources to deliver existing multi-destination traffic, this
	new types of content and use cases that previously were not possible		architecture also enables new types of content and use cases that
	or economically viable using traditional CDN approaches. Finally,		previously were not possible or economically viable using traditional
	TreeDN is a decentralized architecture and a democratizing technology		CDN approaches. Finally, TreeDN is a decentralized architecture and
	in the way that it makes content distribution more accessible to more		a democratizing technology that makes content distribution more
	people by dramatically reducing the costs of replication.		accessible to more people by dramatically reducing the costs of
			replication.
	Status of This Memo		Status of This Memo
	This Internet-Draft is submitted in full conformance with the		This document is not an Internet Standards Track specification; it is
	provisions of BCP 78 and BCP 79.		published for informational purposes.
	Internet-Drafts are working documents of the Internet Engineering
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	Drafts is at https://datatracker.ietf.org/drafts/current/.
	Internet-Drafts are draft documents valid for a maximum of six months		This document is a product of the Internet Engineering Task Force
	and may be updated, replaced, or obsoleted by other documents at any		(IETF). It represents the consensus of the IETF community. It has
	time. It is inappropriate to use Internet-Drafts as reference		received public review and has been approved for publication by the
	material or to cite them other than as "work in progress."		Internet Engineering Steering Group (IESG). Not all documents
			approved by the IESG are candidates for any level of Internet
			Standard; see Section 2 of RFC 7841.
	This Internet-Draft will expire on 22 February 2025.		Information about the current status of this document, any errata,
			and how to provide feedback on it may be obtained at
			https://www.rfc-editor.org/info/rfc9706.
	Copyright Notice		Copyright Notice
	Copyright (c) 2024 IETF Trust and the persons identified as the		Copyright (c) 2024 IETF Trust and the persons identified as the
	document authors. All rights reserved.		document authors. All rights reserved.
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			in the Revised BSD License.
	Table of Contents		Table of Contents
	1. Problem Statement . . . . . . . . . . . . . . . . . . . . . . 2		1. Introduction
	2. Applicability . . . . . . . . . . . . . . . . . . . . . . . . 4		2. Requirements Language
	3. Multicast Challenges in the Past . . . . . . . . . . . . . . 4		3. Problem Statement
	4. TreeDN Architecture . . . . . . . . . . . . . . . . . . . . . 5		4. Applicability
	4.1. TreeDN Overlays . . . . . . . . . . . . . . . . . . . . . 5		5. Multicast Challenges in the Past
	4.2. TreeDN Native On-Net . . . . . . . . . . . . . . . . . . 6		6. TreeDN Architecture
	5. Replication-as-a-Service (RaaS) . . . . . . . . . . . . . . . 7		6.1. TreeDN Overlays
	6. Decentralization/Democratization of Content Sourcing . . . . 8		6.2. TreeDN Native On-Net
	7. Transport Layer-Related Differences between TreeDN and		7. Replication-as-a-Service (RaaS)
	Traditional CDNs . . . . . . . . . . . . . . . . . . . . 8		8. Decentralization/Democratization of Content Sourcing
	7.1. Integration with Unicast . . . . . . . . . . . . . . . . 9		9. Transport-Layer-Related Differences between TreeDN and
	7.2. Reliability, Adaptive Bitrate and Congestion Control . . 9		Traditional CDNs
	7.3. Authorization and Encryption . . . . . . . . . . . . . . 10		9.1. Integration with Unicast
	8. TreeDN Deployments . . . . . . . . . . . . . . . . . . . . . 10		9.2. Reliability, Adaptive Bitrates, and Congestion Control
	9. Operational Considerations . . . . . . . . . . . . . . . . . 11		9.3. Authorization and Encryption
	10. Security Consideration . . . . . . . . . . . . . . . . . . . 11		10. TreeDN Deployments
	11. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 12		11. Operational Considerations
	12. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 12		12. Security Consideration
	13. References . . . . . . . . . . . . . . . . . . . . . . . . . 12		13. IANA Considerations
	13.1. Normative References . . . . . . . . . . . . . . . . . . 12		14. References
	13.2. Informative References . . . . . . . . . . . . . . . . . 13		14.1. Normative References
	Appendix A. Netverses . . . . . . . . . . . . . . . . . . . . . 16		14.2. Informative References
	Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 16		Appendix A. Netverses
			Acknowledgements
			Authors' Addresses
	1. Problem Statement		1. Introduction
			As Internet audience sizes for high-interest live events reach
			unprecedented levels and bitrates climb to support 4K/8K Augmented
			Reality (AR), live streaming can place a unique type of stress upon
			network resources. TreeDN is a tree-based CDN architecture designed
			to address the distinctive scaling challenges of live streaming to
			mass audiences. TreeDN enables operators to offer Replication-as-
			a-Service (RaaS) at a fraction of the cost of traditional, unicast-
			based CDNs; in some cases, there is no additional cost to the
			infrastructure. In addition to efficiently utilizing network
			resources to deliver existing multi-destination traffic, this
			architecture also enables new types of content and use cases that
			previously were not possible or economically viable using traditional
			CDN approaches. Finally, TreeDN is a decentralized architecture and
			a democratizing technology that makes content distribution more
			accessible to more people by dramatically reducing the costs of
			replication.
			2. Requirements Language
			The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
			"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
			"OPTIONAL" in this document are to be interpreted as described in
			BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all
			capitals, as shown here.
			3. Problem Statement
	Live streaming to mass audiences can impose unique demands on network		Live streaming to mass audiences can impose unique demands on network
	resources. For example, live sporting events broadcast over the		resources. For example, live sporting events that broadcast over the
	Internet to end users has much lower tolerance for long playout		Internet to end users have a much lower tolerance for long playout
	buffers than typical on-demand video streaming. Viewers of live		buffers than typical on-demand video streaming. Viewers of live
	sporting events have long been conditioned by broadcast television to		sporting events have long been conditioned by broadcast television to
	expect to see the content in real time, with only very short buffers		expect to see the content in real time, with only very short buffers
	for broadcast delays to prevent profanity and other objectionable		for broadcast delays to prevent profanity and other objectionable
	content from making on the air (the "seven-second delay"		content from making on the air (this is known as the "seven-second
	[BROADCAST-DELAY]). With micro-betting, even this 5-10 second delay		delay" [BROADCAST-DELAY]). With micro-betting, even this 5 to 10
	can be too long. By comparison, when watching on-demand movies, an		second delay can be too long. By comparison, when watching on-demand
	extra one- or two-minute playout buffer tends to be perfectly		movies, an extra one- or two-minute playout buffer tends to be
	acceptable for viewers. If playout buffers for live sports are that		perfectly acceptable for viewers. If playout buffers for live sports
	long, viewers run the risk of being alerted to the game winning score		are that long, viewers run the risk of being alerted to a game-
	from text messages from friends or cheers from the bar across the		winning score from text messages from friends or cheers from the bar
	street, minutes before they view it themselves.		across the street minutes before they view it themselves.
	Another unique characteristic of live streaming is join rate. While		Another unique characteristic of live streaming is the join rate.
	on-demand video streaming can consume massive amounts of network		While on-demand video streaming can consume massive amounts of
	resources, the viewing rates tend to be smooth and predictable.		network resources, the viewing rates tend to be smooth and
	Service Providers observe gradual levels of traffic increases over		predictable. Service Providers (SPs) observe gradual levels of
	the evening hours corresponding to prime-time viewing habits. By		traffic increases over the evening hours corresponding to prime-time
	comparison, viewing rates of live video streams can more closely		viewing habits. By comparison, viewing rates of live video streams
	resemble a step function with much less predictability as mass		can more closely resemble a step function with much less
	audiences of viewers tune in to watch the game at the same time.		predictability as mass audiences of viewers tune in to watch the game
			at the same time.
	Previous efforts at more efficient network replication of multi-		Previous efforts for more efficient network replication of multi-
	destination traffic have experienced mixed success in terms of		destination traffic have experienced mixed success in terms of
	adoption. IP multicast is widely deployed on financial networks,		adoption. IP multicast is widely deployed on financial networks,
	video distribution networks, L3VPN networks and certain enterprises.		video distribution networks, L3VPN networks, and certain enterprises.
	But most of these deployments are restricted to "walled-garden"		However, most of these deployments are restricted to "walled-garden"
	networks. Multicast over the global Internet has failed to gain		networks. Multicast over the global Internet has failed to gain
	traction, as only a very small portion of the Internet is multicast-		traction, as only a very small portion of the Internet is multicast
	enabled at this time.		enabled at this time.
	TreeDN is a tree-based CDN architecture that is the result of the		TreeDN is a tree-based CDN architecture that is the result of the
	evolution of network-based replication mechanisms based on lessons		evolution of network-based replication mechanisms and is based on
	learned from what has and has not worked well in the past. TreeDN		lessons learned from what has and has not worked well in the past.
	addresses the fundamental issues of what has hindered multicast from		TreeDN addresses the fundamental issues of what has hindered
	adoption on the global Internet and enables service providers the		multicast from adoption on the global Internet and enables SPs the
	opportunity to deliver new Replication-as-a-Service (RaaS) offerings		opportunity to deliver new Replication-as-a-Service (RaaS) offerings
	to content providers, while more efficiently utilizing network		to content providers, while more efficiently utilizing network
	resources by eliminating duplicated traffic, and thus, improving the		resources by eliminating duplicated traffic. Thus, this improves the
	experience of end users. TreeDN accomplishes this with the		experience of end users. TreeDN accomplishes this with the
	combination of a simplified model of native multicast along with		combination of a simplified model of native multicast along with
	network overlays to reach receivers on unicast-only parts of the		network overlays to reach receivers on unicast-only parts of the
	Internet.		Internet.
	By more efficiently supporting multi-destination traffic, TreeDN is		By more efficiently supporting multi-destination traffic, TreeDN is
	an architecture that can enable new types of content, such as		an architecture that can enable new types of content (such as AR live
	Augmented Reality (AR) live streaming to mass audiences, that		streaming to mass audiences) that previously weren't possible or
	previously weren't possible or economically viable on the Internet		economically viable on the Internet due to the inefficiencies of
	due to the inefficiencies of unicast.		unicast.
	2. Applicability		4. Applicability
	While the primary use case mentioned throughout this document is live		While the primary use case mentioned throughout this document is live
	streaming of multimedia content (audio, video, AR, real-time		streaming of multimedia content (e.g., audio, video, AR, and real-
	telemetry data), the TreeDN architecture can provide efficient		time telemetry data), the TreeDN architecture can provide efficient
	delivery for any content that needs to be replicated and delivered to		delivery for any content that needs to be replicated and delivered to
	multiple destinations. For example, large software file updates (eg,		multiple destinations. For example, large software file updates
	OS upgrades) that need to be delivered to many end users in a very		(e.g., OS upgrades) that need to be delivered to many end users in a
	short window of time can cause significant strain on network		very short window of time can cause significant strain on network
	resources. Using TreeDN, this use case can be handled much more		resources. Using TreeDN, this use case can be handled much more
	efficiently by the network.		efficiently by the network.
	3. Multicast Challenges in the Past		5. Multicast Challenges in the Past
	The following issues have been the some of the primary challenges for		The following issues have been some of the primary challenges for
	deployment of IP multicast over the global Internet. This is not		deployment of IP multicast over the global Internet. This is not
	intended to be an exhaustive list, but to rather to provide context		intended to be an exhaustive list but rather a list that provides
	to the solution and how it addresses these primary challenges.		context for the solution and how it addresses these primary
			challenges.
	* The "All or Nothing" Problem: IP multicast requires every layer-3		The "All or Nothing" problem: IP multicast requires every Layer 3
	hop between source and receivers to be multicast-enabled. To		hop between the source and receivers to be multicast enabled. To
	achieve ubiquitous availability on the global Internet, this		achieve ubiquitous availability on the global Internet, this
	essentially means nearly every interface on every router and		essentially means that nearly every interface on every router and
	firewall between all end hosts must support a multicast routing		firewall between all end hosts must support a multicast routing
	protocol like Protocol Independent Multicast - Sparse Mode (PIM-		protocol (such as Protocol Independent Multicast - Sparse Mode
	SM) [RFC7761] or Multipoint Label Distribution Protocol (mLDP)		(PIM-SM) [RFC7761] or the Multipoint Label Distribution Protocol
	[RFC6388]. This requirement creates a bar to deployment that is		(mLDP) [RFC6388]). This requirement creates a bar to deployment
	practically impossible to overcome.		that is practically impossible to overcome.
	* The "It's Too Complex" Problem: operators have long complained		The "It's Too Complex" problem: Operators have long complained that
	that multicast routing protocols like PIM-SM are simply too		multicast routing protocols like PIM-SM are simply too complex,
	complex, making it costly to design, configure, manage and		making it costly to design, configure, manage, and troubleshoot IP
	troubleshoot IP multicast in the network.		multicast in the network.
	* The "Chicken and Egg" Problem: there's not much multicast content		The "Chicken and Egg" problem: There's not much multicast content
	because there's not much of a multicast-enabled audience, but		because there's not much of a multicast-enabled audience, but
	there's not much of a multicast-enabled audience because there's		there's not much of a multicast-enabled audience because there's
	not much multicast content.		not much multicast content.
	TreeDN is the evolution of network-based replication based on lessons		TreeDN is the evolution of network-based replication based on lessons
	learned over decades and is designed to address the problems listed		learned over decades and is designed to address the problems listed
	above.		above.
	4. TreeDN Architecture		6. TreeDN Architecture
	TreeDN leverages a simplified model for multicast deployment combined		TreeDN leverages a simplified model for multicast deployment combined
	with network overlays to deliver traffic to receiving hosts on		with network overlays to deliver traffic to receiving hosts on
	unicast-only networks. With network overlays, a service can be		unicast-only networks. With network overlays, a service can be
	achieved and delivered to end users while recognizing and tolerating		achieved and delivered to end users while recognizing and tolerating
	the practical realities of what is possible over a network as diverse		the practical realities of what is possible over a network as diverse
	as the global Internet. That is, the replication service is		as the global Internet. That is, the replication service is
	available to users and applications across the global Internet		available to users and applications across the global Internet
	regardless of what protocols may exist in the underlying networks		regardless of what protocols may exist in the underlying networks
	that constitute the underlay.		that constitute the underlay.
	skipping to change at page 5, line 39 ¶		skipping to change at line 251 ¶
	Native Content AMT Tunnel +-------.------+		Native Content AMT Tunnel +-------.------+
	Receivers .		Receivers .
	AMT +-+		AMT +-+
	Gateway +-+		Gateway +-+
	|		|
	Content		Content
	Receiver		Receiver
	Figure 1: TreeDN Provider Example		Figure 1: TreeDN Provider Example
	4.1. TreeDN Overlays		6.1. TreeDN Overlays
	One overlay technology that TreeDN leverages is Automatic Multicast		One overlay technology that TreeDN leverages is Automatic Multicast
	Tunneling (AMT) [RFC7450]. With AMT, end hosts on unicast-only		Tunneling (AMT) [RFC7450]. With AMT, end hosts on unicast-only
	networks (AMT Gateways) can dynamically build tunnels to routers on		networks (AMT Gateways) can dynamically build tunnels to routers on
	the multicast-enabled part of the network (AMT Relays) and receive		the multicast-enabled part of the network (AMT Relays) and receive
	multicast streams. The AMT Gateway is a thin software client which		multicast streams. The AMT Gateway is a thin software client that
	typically sits on the receiving end host and initiates the tunnel at		typically sits on the receiving end host and initiates the tunnel at
	an AMT Relay, which is a tunnel server that typically sits at the		an AMT Relay. The AMT Relay is a tunnel server that typically sits
	border of the multicast network. AMT allows any end host on the		at the border of the multicast network. AMT allows any end host on
	Internet to receive multicast content regardless of whether their		the Internet to receive multicast content regardless of whether their
	local provider supports multicast (aka, "off-net receivers"), which		local provider supports multicast (aka, "off-net receivers"); this
	addresses the "All or Nothing" Problem. Links and devices that do		addresses the "All or Nothing" problem. Links and devices that do
	not support multicast are simply tunneled over- they no longer		not support multicast are simply tunneled over; they no longer
	present a barrier to the overall replication service for end users.		present a barrier to the overall replication service for end users.
	Those networks that do deploy and support multicast, as well as the		Those networks that do deploy and support multicast, as well as the
	content providers that serve up multicast content, are able to enjoy		content providers that serve up multicast content, are able to enjoy
	the benefits of efficient replication and delivery. Further, these		the benefits of efficient replication and delivery. Further, these
	benefits can serve as incentives for operators who do not yet support		benefits can serve as incentives for operators who do not yet support
	multicast to enable it on their networks, a key benefit of		multicast to enable it on their networks, which is a key benefit of
	incremental deployment described in section 4.3 of [RFC9049]. Once		incremental deployment described in Section 4.3 of [RFC9049]. Once
	the cost of carrying duplicated unicast tunnels is perceived by those		the cost of carrying duplicated unicast tunnels is perceived by those
	operators to exceed the cost of deploying multicast, they are more		operators to exceed the cost of deploying multicast, they are more
	likely to enable multicast on their networks. In this way, TreeDN		likely to enable multicast on their networks. Thus, TreeDN
	effectively supports incremental deployment in a way that was not		effectively supports incremental deployment in a way that was not
	previously possible with traditional (non-overlay) multicast		previously possible with traditional (non-overlay) multicast
	networking. Finally, AMT also addresses the "Chicken and Egg"		networking. Finally, AMT also addresses the "Chicken and Egg"
	Problem, as all end hosts on the global Internet that have access to		problem, as all end hosts on the global Internet that have access to
	an AMT Relay are capable of becoming audience members.		an AMT Relay are capable of becoming audience members.
	To support receiving on both native and non-native networks,		To support receiving on both native and non-native networks,
	receiving hosts can first attempt to join the traffic natively and,		receiving hosts can first attempt to join the traffic natively, and
	if no multicast traffic is received, fallback to AMT. This fallback		if no multicast traffic is received, they can fall back to AMT. This
	mechanism can be handled by the application layer.		fallback mechanism can be handled by the application layer.
	In addition to AMT, other overlay technologies like Locator/ID		In addition to AMT, other overlay technologies like the Locator/ID
	Separation Protocol (LISP) [RFC9300] can be utilized to deliver		Separation Protocol (LISP) [RFC9300] can be utilized to deliver
	content from multicast-enabled networks to end hosts that are		content from multicast-enabled networks to end hosts that are
	separated by portions of the network (at the last/middle/first mile)		separated by portions of the network (at the last/middle/first mile)
	that do not support multicast.		that do not support multicast.
	4.2. TreeDN Native On-Net		6.2. TreeDN Native On-Net
	Networks that support multicast provide the native on-net component		Networks that support multicast provide the native on-net component
	of TreeDN. The primary requirement of the native on-net is to		of TreeDN. The primary requirement of the native on-net is to
	support Source-Specific Multicast (SSM) [RFC4607]. PIM-SSM, which is		support Source-Specific Multicast (SSM) [RFC4607]. PIM-SSM, which is
	merely a subset of PIM-SM, is the multicast routing protocol		merely a subset of PIM-SM, is the multicast routing protocol
	typically used in SSM. However, any multicast routing protocol		typically used in SSM. However, any multicast routing protocol
	capable of supporting SSM can be used as a TreeDN native on-net, such		capable of supporting SSM can be used as a TreeDN native on-net, such
	as mLDP, Global Table Multicast (GTM) [RFC7716] and BGP-based		as mLDP, Global Table Multicast (GTM) [RFC7716] and BGP-based
	Multicast [I-D.ietf-bess-bgp-multicast], or even BGP-MVPN [RFC6513]		multicast [BGP-MULTICAST], or even BGP Multicast VPN (BGP-MVPN)
	for those operators who carry the global routing table in a VRF.		[RFC6513] for those operators who carry the global routing table in a
	Likewise, any data plane technology that supports SSM, including BIER		VRF. Likewise, any data plane technology that supports SSM,
	[RFC8279] and SR-P2MP [I-D.ietf-spring-sr-replication-segment] can be		including Bit Index Explicit Replication (BIER) [RFC8279] and Segment
	used.		Routing (SR) Point-to-Multipoint (P2MP) [RFC9524], can be used.
	The key benefit of SSM as the native on-net component of TreeDN is		The key benefit of SSM as the native on-net component of TreeDN is
	that it radically simplifies the control plane needed to support		that it radically simplifies the control plane needed to support
	replication in the network. This simplification comes by moving		replication in the network. This simplification comes by moving
	source discovery from the network layer to some sort of out-of-band		source discovery from the network layer to some sort of out-of-band
	mechanism, usually in the application layer. In SSM, the receiver		mechanism, usually in the application layer. In SSM, the receiver
	uses Internet Group Management Protocol, Version 3 (IGMPv3) [RFC3376]		uses the Internet Group Management Protocol Version 3 (IGMPv3)
	for IPv4 or Multicast Listener Discovery Version 2 (MLDv2) [RFC3810]		[RFC3376] for IPv4 or the Multicast Listener Discovery Version 2
	for IPv6 to specify both the source and group address of the		(MLDv2) protocol [RFC3810] for IPv6 to specify both the source and
	multicast stream. This allows the last hop router to immediately		group address of the multicast stream. This allows the last-hop
	join the multicast stream along the shortest-path tree (SPT) without		router to immediately join the multicast stream along the shortest-
	the need for shared trees. This benefit addresses the "It's Too		path tree (SPT) without the need for shared trees. This benefit
	Complex" Problem. By eliminating the need for network-based source		addresses the "It's Too Complex" problem. By eliminating the need
	discovery, most of the complexity of multicast is then eliminated,		for network-based source discovery, most of the complexity of
	which reduces the cost of deploying and operating a multicast		multicast is then eliminated, which reduces the cost of deploying and
	network. Further rationale for this SSM-only approach can be found		operating a multicast network. Further rationale for this SSM-only
	in Any-Source Multicast (ASM) Deprecation [RFC8815].		approach can be found in Any-Source Multicast (ASM) deprecation
			[RFC8815].
	5. Replication-as-a-Service (RaaS)		7. Replication-as-a-Service (RaaS)
	Content providers have traditionally used CDNs to distribute content		Content providers have traditionally used CDNs to distribute content
	that needs to be delivered to large audiences, essentially		that needs to be delivered to large audiences, essentially
	outsourcing the task of replication to CDN providers. Most CDNs		outsourcing the task of replication to CDN providers. Most CDNs
	utilize unicast delivery, as multicast is not an option due to its		utilize unicast delivery, as multicast is not an option due to its
	lack of general availability on the global Internet. TreeDN is a CDN		lack of general availability on the global Internet. TreeDN is a CDN
	architecture that leverages tree-based replication to more		architecture that leverages tree-based replication to more
	efficiently utilize network resources to deliver simultaneous multi-		efficiently utilize network resources to deliver simultaneous multi-
	destination traffic. By leveraging overlay networking to address the		destination traffic. By leveraging overlay networking to address the
	"All or Nothing" and "Chicken and Egg" Problems and SSM to address		"All or Nothing" and "Chicken and Egg" problems, and leveraging SSM
	the "It's Too Complex" Problem, TreeDN avoids the practical issues		to address the "It's Too Complex" problem, TreeDN avoids the
	that previously prevented multicast from being a viable option for		practical issues that previously prevented multicast from being a
	CDN providers.		viable option for CDN providers.
	TreeDN has several advantages over traditional unicast-based CDN		TreeDN has several advantages over traditional unicast-based CDN
	approaches. First, the TreeDN functionality can be delivered		approaches. First, the TreeDN functionality can be delivered
	entirely by the existing network infrastructure. Specifically, for		entirely by the existing network infrastructure. Specifically, for
	operators with routers that support AMT natively, multicast traffic		operators with routers that support AMT natively, multicast traffic
	can be delivered directly to end users without the need for		can be delivered directly to end users without the need for
	specialized CDN devices, which typically are servers that need to be		specialized CDN devices, which typically are servers that need to be
	racked, powered, cooled and connected to ports on routers that could		racked, powered, cooled, and connected to ports on routers that
	otherwise have been consumed by paying customers. In this way, SPs		otherwise could have been consumed by paying customers. In this way,
	can offer new RaaS functionality to content providers at potentially		SPs can offer new RaaS functionality to content providers at
	zero additional cost in new equipment.		potentially zero additional cost in new equipment.
	Additionally, TreeDN is an open architecture that leverages mature,		Additionally, TreeDN is an open architecture that leverages mature,
	IETF-specified and widely implemented network protocols. TreeDN also		IETF-specified, and widely implemented network protocols. TreeDN
	requires far less coordination between the content provider and the		also requires far less coordination between the content provider and
	CDN operator. That is, there are no storage requirements for the		the CDN operator. That is, there are no storage requirements for the
	data, nor group-key management issues since a TreeDN provider merely		data, nor group-key management issues, since a TreeDN provider merely
	forwards packets. A TreeDN provider simply needs to have enough		forwards packets. A TreeDN provider simply needs to have enough
	accounting data (eg, traffic data, number of AMT tunnels, etc) to		accounting data (e.g., traffic data, number of AMT tunnels, etc.) to
	properly bill customers for the service. By contrast, traditional		properly bill customers for the service. By contrast, traditional
	unicast-based CDNs often incorporate proprietary, non-interoperable		unicast-based CDNs often incorporate proprietary, non-interoperable
	technologies and require significant coordination between the content		technologies and require significant coordination between the content
	provider and the CDN to handle such things as file storage, data		provider and the CDN to handle such things as file storage, data
	protection and key-management.		protection, and key management.
	TreeDN introduces a deployment model that requires new considerations		TreeDN introduces a deployment model that requires new considerations
	for transport layer mechanisms that are frequently relied upon by		for transport-layer mechanisms that are frequently relied upon by
	traditional unicast-based CDNs. A discussion on these considerations		traditional unicast-based CDNs. A discussion on these considerations
	and differences can be found in section 7.		and differences can be found in Section 8.
	6. Decentralization/Democratization of Content Sourcing		8. Decentralization/Democratization of Content Sourcing
	TreeDN is an inherently decentralized architecture. This reduces the		TreeDN is an inherently decentralized architecture. This reduces the
	cost for content sourcing, as any host connected to a multicast-		cost for content sourcing, as any host connected to a multicast-
	enabled network, or on a source-capable overlay, can send out a		enabled network or on a source-capable overlay can send out a single
	single data stream that can be reached by an arbitrarily large		data stream that can be reached by an arbitrarily large audience. By
	audience. By effectively reducing to zero the marginal cost of		effectively reducing the marginal cost of reaching each additional
	reaching each additional audience member, from the perspective of the		audience member to zero, from the perspective of the source, TreeDN
	source, TreeDN democratizes content sourcing on the Internet.		democratizes content sourcing on the Internet.
	7. Transport Layer-Related Differences between TreeDN and Traditional		9. Transport-Layer-Related Differences between TreeDN and Traditional
	CDNs		CDNs
	The focus of this document is on the network layer components that		The focus of this document is on the network-layer components that
	comprise the TreeDN architecture. This section introduces some of		comprise the TreeDN architecture. This section introduces some of
	the key transport layer-related differences between TreeDN and		the key transport-layer-related differences between TreeDN and
	traditional unicast-based CDNs that should be taken into		traditional unicast-based CDNs that should be taken into
	consideration when deploying TreeDN-based services. In many cases,		consideration when deploying TreeDN-based services. In many cases,
	these issues are more related to TCP-UDP differences than unicast-		these issues are more related to TCP-UDP differences than unicast-
	multicast differences, thus UDP-based solutions can be leveraged to		multicast differences; thus, UDP-based solutions can be leveraged to
	address most gaps. The aim of this section is to point to some of		address most gaps. The aim of this section is to point to some of
	the existing work to address these gaps, as well as suggest further		the existing work to address these gaps, as well as to suggest
	work that could be undertaken within the IETF. Further details of		further work that could be undertaken within the IETF. Further
	these transport layer mechanisms are beyond the scope of this		details of these transport-layer mechanisms are beyond the scope of
	document.		this document.
	7.1. Integration with Unicast		9.1. Integration with Unicast
	Since SSM inherently implies unidirectional traffic flows from one to		Since SSM inherently implies unidirectional traffic flows from one to
	many, mechanisms that rely on bidirectional communication between		many, mechanisms that rely on bidirectional communication between
	receivers and the content provider, such as bespoke advertising,		receivers and the content provider, such as bespoke advertising,
	telemetry data from receivers detailing end user experience,		telemetry data from receivers detailing end-user experience,
	distribution of decryption keys, switching to higher/lower bandwidth		distribution of decryption keys, switching to higher/lower bandwidth
	streams, etc, are not well suited to SSM delivery. As such, separate		streams, etc., are not well suited to SSM delivery. As such,
	unicast streams between receivers and content providers may be used		separate unicast streams between receivers and content providers may
	for this type of "out-of-band" functions while SSM is used to deliver		be used for this type of "out-of-band" function while SSM is used to
	the actual content of interest. These "out-of-band" unicast streams		deliver the actual content of interest. These "out-of-band" unicast
	SHOULD use the same congestion control and authentication mechanisms		streams SHOULD use the same congestion control and authentication
	that are used today for mass audience unicast delivery. Generally		mechanisms that are used today for mass audience unicast delivery.
	speaking, this hybrid unicast-multicast approach is best handled by		Generally speaking, this hybrid unicast-multicast approach is best
	the application layer and further detail is beyond the scope of this		handled by the application layer and further detail is beyond the
	document.		scope of this document.
	7.2. Reliability, Adaptive Bitrate and Congestion Control		9.2. Reliability, Adaptive Bitrates, and Congestion Control
	Traditional unicast-based CDNs frequently rely on HTTPS over TCP		Traditional unicast-based CDNs frequently rely on HTTPS over TCP
	transport and are thus able to leverage the granularity of TCP-based		transport; thus, they are able to leverage the granularity of TCP-
	mechanisms for reliability, congestion control and adaptive bitrate		based mechanisms for reliability, congestion control, and adaptive
	streaming. But this granularity comes at a cost of sending a		bitrate streaming. However, this granularity comes at a cost of
	separate datastream to each viewer. Multicast transmissions usually		sending a separate data stream to each viewer. Multicast
	employ UDP, which inherently lacks many of the aforementioned		transmissions usually employ UDP, which inherently lacks many of the
	benefits of TCP, but can scale much better for mass audiences of		aforementioned benefits of TCP but can scale much better for mass
	simultaneous viewers. Forward Error Correction (FEC) is a mechanism		audiences of simultaneous viewers. Forward Error Correction (FEC) is
	that has demonstrated full recovery for up to 5% packet loss and		a mechanism that has demonstrated full recovery for up to 5% packet
	interruptions up to 400ms for multicast datastreams in		loss and interruptions up to 400 ms for multicast data streams in
	[EUMETSAT-TERRESTRIAL]. NACK-Oriented Reliable Multicast (NORM)		[EUMETSAT-TERRESTRIAL]. NACK-Oriented Reliable Multicast (NORM)
	[RFC5740] leverages FEC-based repair and other Reliable Multicast		[RFC5740] leverages FEC-based repair and other Reliable Multicast
	Transport building blocks to provide end-to-end reliable transport		Transport (RMT) building blocks to provide end-to-end reliable
	over multicast networks.		transport over multicast networks.
	QUIC [RFC9000] is another popular transport used by traditional		QUIC [RFC9000] is another popular transport used by traditional
	unicast-based CDNs. While QUIC does use UDP, it does not currently		unicast-based CDNs. While QUIC does use UDP, it does not currently
	support multicast. Multicast extensions to QUIC have been proposed		support multicast. Multicast extensions to QUIC have been proposed
	in [I-D.jholland-quic-multicast].		in [QUIC-Multicast].
	Section 4.1 of [RFC8085] describes how a sender can distribute data		Section 4.1 of [RFC8085] describes how a sender can distribute data
	across multiple multicast source-group channels so that each receiver		across multiple multicast source-group channels so that each receiver
	can join the most appropriate channels for its own reception rate		can join the most appropriate channels for its own reception rate
	capability, thus providing adaptive bitrate capabilities for		capability, thus providing adaptive bitrate capabilities for
	multicast streams. DVB MABR [DVB-MABR] and MAUD [MAUD] extensively		multicast streams. [DVB-MABR] and [MAUD] extensively describe an
	describe an architecture that enables reliability and dynamic bitrate		architecture that enables reliability and dynamic bitrate adaptation.
	adaptation.
	TreeDN deployments MUST follow the congestion control guidelines		TreeDN deployments MUST follow the congestion control guidelines
	described in Section 4.1.4.2 of [RFC7450]. Multicast applications		described in Section 4.1.4.2 of [RFC7450]. A multicast application
	being distributed over TreeDN deployments SHOULD implement congestion		that is being distributed over TreeDN deployments SHOULD implement
	control for its data transmission as described in Section 4.1 in		congestion control for its data transmission as described in
	[RFC8085]. The AMT gateway SHOULD use the topologically closest AMT		Section 4.1 of [RFC8085]. The AMT gateway SHOULD use the
	relay. Section 3.1 of [RFC8777] describes a set of procedures for		topologically closest AMT relay. Section 3.1 of [RFC8777] describes
	optimal relay selection.		a set of procedures for optimal relay selection.
	7.3. Authorization and Encryption		9.3. Authorization and Encryption
	A multicast sender typically has little to no control or visibility		A multicast sender typically has little to no control or visibility
	about which end hosts may receive the datastream. Encryption can be		about which end hosts may receive the data stream. Encryption can be
	used to ensure that only authorized receivers are able to access		used to ensure that only authorized receivers are able to access
	meaningful data. That is, even if unauthorized end hosts (eg, non-		meaningful data. That is, even if unauthorized end hosts (e.g., non-
	paying) receive the datastream, without decryption keys, the data is		paying) receive the data stream, without decryption keys, the data is
	useless. [I-D.ietf-ipsecme-g-ikev2] describes an extension to IKEv2		useless. [GKM-IKEv2] describes an extension to the Internet Key
	for the purpose of group key management. DVB MABR [DVB-MABR] and		Exchange Protocol Version 2 (IKEv2) for the purpose of group key
	MAUD [MAUD] extensively describe an architecture that includes		management. [DVB-MABR] and [MAUD] extensively describe an
	encryption of multicast streams.		architecture that includes encryption of multicast streams.
	8. TreeDN Deployments		10. TreeDN Deployments
	EUMETCast Terrestrial is a service from EUMETSAT that delivers		EUMETCast Terrestrial is a service from the European Organisation for
	meteorological satellite data to end users for purposes such as		the Exploitation of Meteorological Satellites (EUMETSAT) that
	operational monitoring of climate and detection of global climate		delivers meteorological satellite data to end users for purposes such
			as operational monitoring of climates and detection of global climate
	changes. EUMETCast Terrestrial connects to the GEANT network, which		changes. EUMETCast Terrestrial connects to the GEANT network, which
	provides TreeDN services to deliver this real-time data natively to		provides TreeDN services to deliver this real-time data natively to
	end users on multicast-enabled networks as well as to end users on		end users on multicast-enabled networks and to end users on unicast-
	unicast-only networks via a global deployment of AMT relays. Details		only networks via a global deployment of AMT relays. Details of the
	of the EUMETCast Terrestrial service over the GEANT TreeDN network		EUMETCast Terrestrial service over the GEANT TreeDN network are
	are described in [EUMETCast-TERRESTRIAL-over-AMT]. Additional		described in [EUMETCast-TERRESTRIAL-AMT]. Additional details on how
	details on how this deployment uses encryption, authorization,		this deployment uses encryption, authorization, reliability, and
	reliability and unicast feedback channels for end-to-end file		unicast feedback channels for end-to-end file delivery monitoring can
	delivery monitoring can be found in [EUMETSAT-TERRESTRIAL].		be found in [EUMETSAT-TERRESTRIAL].
	The Multicast Menu is a web-based portal that lists and can launch		The Multicast Menu is a web-based portal that can list and launch
	active multicast streams that are available on a global TreeDN		active multicast streams that are available on a global TreeDN
	network of various research and educations networks. Details of the		network of various research and education networks. Details of this
	this TreeDN network, as well as the Multicast Menu, are described in		TreeDN network, as well as the Multicast Menu, are described in
	[Multicast-Menu].		[Multicast-Menu].
	The RARE network is a global testbed interconnecting several national		The RARE network is a global testbed interconnecting several National
	research and education networks (NRENs) via routers running BIER.		Research and Education Networks (NRENs) via routers running BIER.
	AMT relays are deployed to deliver multicast traffic from sources on		AMT relays are deployed to deliver multicast traffic from sources on
	the RARE network to receivers on unicast-only networks across the		the RARE network to receivers on unicast-only networks across the
	Internet. Details of the RARE network are described in		Internet. Details of the RARE network are described in
	[BIER-AMT-Deployment].		[BIER-AMT-Deployment].
	9. Operational Considerations		11. Operational Considerations
	TreeDN is essentially the synthesis of SSM plus overlay networking		TreeDN is essentially the synthesis of SSM plus overlay networking
	technologies like AMT. As such, any existing tools to manage,		technologies like AMT. As such, any existing tools to manage,
	operate and troubleshoot a PIM-SSM domain and AMT deployment can be		operate, and troubleshoot a PIM-SSM domain and an AMT deployment can
	used to manage a TreeDN deployment. Protocol error handling for PIM-		be used to manage a TreeDN deployment. Protocol error handling for
	SSM can be found in [RFC4607] and in section 4.8 of [RFC7761] and for		PIM-SSM can be found in [RFC4607] and in Section 4.8 of [RFC7761];
	AMT in [RFC7450].		for AMT, it can be found in [RFC7450].
	One potential operational benefit of a multicast-based approach like		One potential operational benefit of a multicast-based approach like
	TreeDN over traditional, unicast-based CDNs is the visibility that		TreeDN over a traditional, unicast-based CDN is the visibility that
	multicast state provides in the routing infrastructure. That is,		multicast state provides in the routing infrastructure. That is,
	multicast routers maintain a forwarding cache of multicast flows that		multicast routers maintain a forwarding cache of multicast flows that
	usually includes the source address, group address, incoming/outgoing		usually includes the source address, group address, incoming/outgoing
	interfaces and forwarding rate. Generally speaking, such flow state		interfaces, and forwarding rate. Generally speaking, such flow state
	information is not typically available in core networks for unicast,		information is not typically available in core networks for unicast,
	so additional tools outside the routing infrastructure are usually		so additional tools outside the routing infrastructure are usually
	required for monitoring CDN performance and troubleshooting issues		required for monitoring CDN performance and troubleshooting issues
	like packet loss location. Of course, this benefit comes at a cost		like packet loss location. Of course, this benefit comes at a cost
	of additional state being maintained in the routers for multicast.		of additional state being maintained in the routers for multicast.
	Additionally, since multicast leverages reverse-path forwarding		Additionally, since multicast leverages Reverse Path Forwarding
	(RPF), the source of the content can potentially have a greater		(RPF), the source of the content can potentially have a greater
	influence over the path taken through the network from source to		influence over the path taken through the network from source to
	native receivers/AMT relays. That is, the BGP peer advertising the		native receivers/AMT relays. That is, the BGP peer advertising the
	reachability of the source's subnet can do so in ways that can prefer		reachability of the source's subnet can do so in ways that can prefer
	a particular path through the network for multicast distribution that		a particular path through the network for multicast distribution that
	are not as easy to accomplish with traditional, destination-based		are not as easy to accomplish with traditional, destination-based
	unicast routing.		unicast routing.
	10. Security Consideration		12. Security Consideration
	Since TreeDN is essentially the synthesis of SSM plus overlay		Since TreeDN is essentially the synthesis of SSM plus overlay
	networking technologies like AMT, the TreeDN architecture introduces		networking technologies like AMT, the TreeDN architecture introduces
	no new security threats that are not already documented in SSM and		no new security threats that are not already documented in SSM and
	the overlay technologies that comprise it. In particular, Section 6		the overlay technologies that comprise it. In particular, Section 6
	of [RFC7450] candidly notes that AMT, like UDP, IGMP and MLD,		of [RFC7450] candidly notes that AMT, like UDP, IGMP, and MLD,
	provides no mechanisms for ensuring message delivery or integrity,		provides no mechanisms for ensuring message delivery or integrity,
	nor does it provide confidentiality, since sources/groups joined		nor does it provide confidentiality, since sources/groups joined
	through IGMP/MLD could be associated with the particular content		through IGMP/MLD could be associated with the particular content
	being requested.		being requested.
	[RFC4609] and [RFC8815] describes the additional security benefits of		[RFC4609] and [RFC8815] describe the additional security benefits of
	using SSM instead of ASM.		using SSM instead of ASM.
	11. IANA Considerations		13. IANA Considerations
	This document has no IANA actions.		This document has no IANA actions.
	12. Acknowledgements		14. References
	Many thanks to those who have contributed to building and operating
	the first TreeDN network on the Internet, including Pete Morasca,
	William Zhang, Lauren Delwiche, Natalie Landsberg, Wayne Brassem,
	Jake Holland, Andrew Gallo, Casey Russell, Janus Varmarken, Csaba
	Mate, Frederic Loui, Max Franke, Todor Moskov, Erik Herz, Bradley
	Cao, Katie Merrill, Karel Hendrych, Haruna Oseni and Isabelle Xiong.
	The writing of this document to describe the TreeDN architecture was
	inspired by a conversation with Dino Farinacci and Mike McBride.
	Thanks also to Jeff Haas, Vinod Kumar, Ron Bonica, Jeffrey Zhang and
	Eric Vyncke for their thoughtful reviews and suggestions, Chris
	Lemmons for his detailed shepherd review and Stephen Farrell, Magnus
	Westerlund, Reese Enghardt, Jurgen Schonwalder, Carlos Pignataro,
	Erik Kline, Gunter Van de Velde, Warren Kumari and Zaheduzzaman
	Sarker for their last call reviews.
	13. References		14.1. Normative References
	13.1. Normative References		[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
			Requirement Levels", BCP 14, RFC 2119,
			DOI 10.17487/RFC2119, March 1997,
			<https://www.rfc-editor.org/info/rfc2119>.
	[RFC3376] Cain, B., Deering, S., Kouvelas, I., Fenner, B., and A.		[RFC3376] Cain, B., Deering, S., Kouvelas, I., Fenner, B., and A.
	Thyagarajan, "Internet Group Management Protocol, Version		Thyagarajan, "Internet Group Management Protocol, Version
	3", RFC 3376, DOI 10.17487/RFC3376, October 2002,		3", RFC 3376, DOI 10.17487/RFC3376, October 2002,
	<https://www.rfc-editor.org/info/rfc3376>.		<https://www.rfc-editor.org/info/rfc3376>.
	[RFC3810] Vida, R., Ed. and L. Costa, Ed., "Multicast Listener		[RFC3810] Vida, R., Ed. and L. Costa, Ed., "Multicast Listener
	Discovery Version 2 (MLDv2) for IPv6", RFC 3810,		Discovery Version 2 (MLDv2) for IPv6", RFC 3810,
	DOI 10.17487/RFC3810, June 2004,		DOI 10.17487/RFC3810, June 2004,
	<https://www.rfc-editor.org/info/rfc3810>.		<https://www.rfc-editor.org/info/rfc3810>.
	skipping to change at page 13, line 11 ¶		skipping to change at line 578 ¶
	[RFC7450] Bumgardner, G., "Automatic Multicast Tunneling", RFC 7450,		[RFC7450] Bumgardner, G., "Automatic Multicast Tunneling", RFC 7450,
	DOI 10.17487/RFC7450, February 2015,		DOI 10.17487/RFC7450, February 2015,
	<https://www.rfc-editor.org/info/rfc7450>.		<https://www.rfc-editor.org/info/rfc7450>.
	[RFC7761] Fenner, B., Handley, M., Holbrook, H., Kouvelas, I.,		[RFC7761] Fenner, B., Handley, M., Holbrook, H., Kouvelas, I.,
	Parekh, R., Zhang, Z., and L. Zheng, "Protocol Independent		Parekh, R., Zhang, Z., and L. Zheng, "Protocol Independent
	Multicast - Sparse Mode (PIM-SM): Protocol Specification		Multicast - Sparse Mode (PIM-SM): Protocol Specification
	(Revised)", STD 83, RFC 7761, DOI 10.17487/RFC7761, March		(Revised)", STD 83, RFC 7761, DOI 10.17487/RFC7761, March
	2016, <https://www.rfc-editor.org/info/rfc7761>.		2016, <https://www.rfc-editor.org/info/rfc7761>.
	13.2. Informative References		[RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
			2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
			May 2017, <https://www.rfc-editor.org/info/rfc8174>.
			14.2. Informative References
	[Algorhyme]		[Algorhyme]
	"Algorhyme", Wikipedia , n.d.,		Wikipedia, "Radia Perlman", September 2024,
	<https://en.wikipedia.org/wiki/		<https://en.wikipedia.org/w/
	Radia_Perlman#Spanning_Tree_Protocol>.		index.php?title=Radia_Perlman&oldid=1245484160>.
			[BGP-MULTICAST]
			Zhang, Z. J., Giuliano, L., Patel, K., Wijnands, I.,
			Mishra, M. P., and A. Gulko, "BGP Based Multicast", Work
			in Progress, Internet-Draft, draft-ietf-bess-bgp-
			multicast-08, 3 June 2024,
			<https://datatracker.ietf.org/doc/html/draft-ietf-bess-
			bgp-multicast-08>.
	[BIER-AMT-Deployment]		[BIER-AMT-Deployment]
	"BIER + AMT Deployment in GEANT/RARE Network", IETF112		Mate, C. and F. Loui, "BIER + AMT Deployment in GEANT/RARE
	Proceedings , n.d.,		Network", IETF 112 Proceedings, November 2021,
	<https://datatracker.ietf.org/meeting/112/materials/		<https://datatracker.ietf.org/meeting/112/materials/
	slides-112-mboned-bier-amt-depolyment-in-geantrare-		slides-112-mboned-bier-amt-depolyment-in-geantrare-
	network-00>.		network-00>.
	[BROADCAST-DELAY]		[BROADCAST-DELAY]
	"Broadcast Delay", Wikipedia , n.d.,		Wikipedia, "Broadcast delay", May 2024,
	<https://en.wikipedia.org/wiki/Broadcast_delay>.		<https://en.wikipedia.org/w/
			index.php?title=Broadcast_delay&oldid=1225656951>.
	[DVB-MABR] "Adaptive media streaming over IP multicast", DVB Document		[DVB-MABR] DVB Project, "Adaptive media streaming over IP multicast",
	A176 Rev.3 (Fourth edition) , n.d., <https://dvb.org/wp-		DVB Document A176 Rev.3 (Fourth edition), March 2023,
	content/uploads/2022/01/A176r3_Adaptive-Media-Streaming-		<https://dvb.org/wp-content/uploads/2022/01/
	over-IP-Multicast_Interim-Draft-TS-		A176r3_Adaptive-Media-Streaming-over-IP-Multicast_Interim-
	103-769-v121_March_2023.pdf>.		Draft-TS-103-769-v121_March_2023.pdf>.
	[EUMETCast-TERRESTRIAL-over-AMT]		[EUMETCast-TERRESTRIAL-AMT]
	"EUMETCast Terrestrial over AMT", IETF115 Proceedings ,		Britton, R. and R. Adam, "EUMETCast Terrestrial over AMT",
	n.d., <https://datatracker.ietf.org/meeting/115/materials/		IETF 115 Proceedings, September 2022,
			<https://datatracker.ietf.org/meeting/115/materials/
	slides-115-mboned-eumetcast-over-amt>.		slides-115-mboned-eumetcast-over-amt>.
	[EUMETSAT-TERRESTRIAL]		[EUMETSAT-TERRESTRIAL]
	"EUMETSAT Terrestrial Service", IETF110 Proceedings ,		Espanyol, O., "EUMETSAT Terrestrial Service", IETF 110
	n.d., <https://datatracker.ietf.org/meeting/110/materials/		Proceedings, February 2021,
			<https://datatracker.ietf.org/meeting/110/materials/
	slides-110-mboned-eumetsat-multicast-over-the-mbone-00>.		slides-110-mboned-eumetsat-multicast-over-the-mbone-00>.
	[I-D.ietf-bess-bgp-multicast]		[GKM-IKEv2]
	Zhang, Z. J., Giuliano, L., Patel, K., Wijnands, I.,
	Mishra, M. P., and A. Gulko, "BGP Based Multicast", Work
	in Progress, Internet-Draft, draft-ietf-bess-bgp-
	multicast-08, 3 June 2024,
	<https://datatracker.ietf.org/doc/html/draft-ietf-bess-
	bgp-multicast-08>.
	[I-D.ietf-ipsecme-g-ikev2]
	Smyslov, V. and B. Weis, "Group Key Management using		Smyslov, V. and B. Weis, "Group Key Management using
	IKEv2", Work in Progress, Internet-Draft, draft-ietf-		IKEv2", Work in Progress, Internet-Draft, draft-ietf-
	ipsecme-g-ikev2-13, 21 August 2024,		ipsecme-g-ikev2-18, 11 December 2024,
	<https://datatracker.ietf.org/api/v1/doc/document/draft-		<https://datatracker.ietf.org/doc/html/draft-ietf-ipsecme-
	ietf-ipsecme-g-ikev2/>.		g-ikev2-18>.
	[I-D.ietf-spring-sr-replication-segment]		[MAUD] Nilsson, M. E., Turnbull, R. S., Stevens, T. S., and S.
	Voyer, D., Filsfils, C., Parekh, R., Bidgoli, H., and Z.		Appleby, "Multicast-Assisted Unicast Delivery", IBC2023
	J. Zhang, "SR Replication segment for Multi-point Service		Tech Papers, September 2023, <https://www.ibc.org/
	Delivery", Work in Progress, Internet-Draft, draft-ietf-		technical-papers/ibc2023-tech-papers-multicast-assisted-
	spring-sr-replication-segment-19, 28 August 2023,		unicast-delivery/10235.article>.
	<https://datatracker.ietf.org/doc/html/draft-ietf-spring-
	sr-replication-segment-19>.
	[I-D.jholland-quic-multicast]		[Multicast-Menu]
			Delwiche, L., "Offnet Sourcing with the Multicast Menu",
			IETF 114 Proceedings, July 2022,
			<https://datatracker.ietf.org/meeting/114/materials/
			slides-114-mboned-offnet-sourcing-with-the-multicast-menu-
			01>.
			[QUIC-Multicast]
	Holland, J., Pardue, L., and M. Franke, "Multicast		Holland, J., Pardue, L., and M. Franke, "Multicast
	Extension for QUIC", Work in Progress, Internet-Draft,		Extension for QUIC", Work in Progress, Internet-Draft,
	draft-jholland-quic-multicast-05, 7 July 2024,		draft-jholland-quic-multicast-05, 7 July 2024,
	<https://datatracker.ietf.org/doc/html/draft-jholland-		<https://datatracker.ietf.org/doc/html/draft-jholland-
	quic-multicast-05>.		quic-multicast-05>.
	[MAUD] "Multicast-Assisted Unicast Delivery", IBC2023 Tech
	Papers , n.d., <https://www.ibc.org/technical-papers/
	ibc2023-tech-papers-multicast-assisted-unicast-
	delivery/10235.article>.
	[Multicast-Menu]
	"Offnet Sourcing with the Multicast Menu", IETF114
	Proceedings , n.d.,
	<https://datatracker.ietf.org/meeting/114/materials/
	slides-114-mboned-offnet-sourcing-with-the-multicast-menu-
	01>.
	[RFC4609] Savola, P., Lehtonen, R., and D. Meyer, "Protocol		[RFC4609] Savola, P., Lehtonen, R., and D. Meyer, "Protocol
	Independent Multicast - Sparse Mode (PIM-SM) Multicast		Independent Multicast - Sparse Mode (PIM-SM) Multicast
	Routing Security Issues and Enhancements", RFC 4609,		Routing Security Issues and Enhancements", RFC 4609,
	DOI 10.17487/RFC4609, October 2006,		DOI 10.17487/RFC4609, October 2006,
	<https://www.rfc-editor.org/info/rfc4609>.		<https://www.rfc-editor.org/info/rfc4609>.
	[RFC5740] Adamson, B., Bormann, C., Handley, M., and J. Macker,		[RFC5740] Adamson, B., Bormann, C., Handley, M., and J. Macker,
	"NACK-Oriented Reliable Multicast (NORM) Transport		"NACK-Oriented Reliable Multicast (NORM) Transport
	Protocol", RFC 5740, DOI 10.17487/RFC5740, November 2009,		Protocol", RFC 5740, DOI 10.17487/RFC5740, November 2009,
	<https://www.rfc-editor.org/info/rfc5740>.		<https://www.rfc-editor.org/info/rfc5740>.
	skipping to change at page 15, line 45 ¶		skipping to change at line 709 ¶
	[RFC9049] Dawkins, S., Ed., "Path Aware Networking: Obstacles to		[RFC9049] Dawkins, S., Ed., "Path Aware Networking: Obstacles to
	Deployment (A Bestiary of Roads Not Taken)", RFC 9049,		Deployment (A Bestiary of Roads Not Taken)", RFC 9049,
	DOI 10.17487/RFC9049, June 2021,		DOI 10.17487/RFC9049, June 2021,
	<https://www.rfc-editor.org/info/rfc9049>.		<https://www.rfc-editor.org/info/rfc9049>.
	[RFC9300] Farinacci, D., Fuller, V., Meyer, D., Lewis, D., and A.		[RFC9300] Farinacci, D., Fuller, V., Meyer, D., Lewis, D., and A.
	Cabellos, Ed., "The Locator/ID Separation Protocol		Cabellos, Ed., "The Locator/ID Separation Protocol
	(LISP)", RFC 9300, DOI 10.17487/RFC9300, October 2022,		(LISP)", RFC 9300, DOI 10.17487/RFC9300, October 2022,
	<https://www.rfc-editor.org/info/rfc9300>.		<https://www.rfc-editor.org/info/rfc9300>.
	[Trees] "Trees", Poetry Foundation , n.d.,		[RFC9524] Voyer, D., Ed., Filsfils, C., Parekh, R., Bidgoli, H., and
			Z. Zhang, "Segment Routing Replication for Multipoint
			Service Delivery", RFC 9524, DOI 10.17487/RFC9524,
			February 2024, <https://www.rfc-editor.org/info/rfc9524>.
			[Trees] Kilmer, J., "Trees", Poetry Foundation,
	<https://www.poetryfoundation.org/poetrymagazine/		<https://www.poetryfoundation.org/poetrymagazine/
	poems/12744/trees>.		poems/12744/trees>.
	Appendix A. Netverses		Appendix A. Netverses
	With inspiration from (and apologies to) Radia Perlman [Algorhyme]		With inspiration from (and apologies to) Radia Perlman [Algorhyme]
	and Joyce Kilmer [Trees], the following poem is not intended to		and Joyce Kilmer [Trees], the following poem is not intended to
	provide any normative or informative technical value on TreeDN beyond		provide any normative or informative technical value on TreeDN beyond
	(mild) amusement for the reader who made it this far in the document:		(mild) amusement for the reader who made it this far in the document:
	skipping to change at page 16, line 30 ¶		skipping to change at line 743 ¶
	A tree extended by AMT,		A tree extended by AMT,
	Enabling unicast-only receivers full delivery.		Enabling unicast-only receivers full delivery.
	A tree that scales to reach millions of places		A tree that scales to reach millions of places
	To viably support the highest of bitrate use cases.		To viably support the highest of bitrate use cases.
	A CDN is built by folks like me,		A CDN is built by folks like me,
	But only end users can generate enough demand to necessitate a tree.		But only end users can generate enough demand to necessitate a tree.
			Acknowledgements
			Many thanks to those who have contributed to building and operating
			the first TreeDN network on the Internet, including Pete Morasca,
			William Zhang, Lauren Delwiche, Natalie Landsberg, Wayne Brassem,
			Jake Holland, Andrew Gallo, Casey Russell, Janus Varmarken, Csaba
			Mate, Frederic Loui, Max Franke, Todor Moskov, Erik Herz, Bradley
			Cao, Katie Merrill, Karel Hendrych, Haruna Oseni, and Isabelle Xiong.
			The writing of this document to describe the TreeDN architecture was
			inspired by a conversation with Dino Farinacci and Mike McBride.
			Thanks also to Jeff Haas, Vinod Kumar, Ron Bonica, Jeffrey Zhang, and
			Éric Vyncke for their thoughtful reviews and suggestions, Chris
			Lemmons for his detailed shepherd review, and Stephen Farrell, Magnus
			Westerlund, Reese Enghardt, Jurgen Schonwalder, Carlos Pignataro,
			Erik Kline, Gunter Van de Velde, Warren Kumari, and Zaheduzzaman
			Sarker for their last call reviews.
	Authors' Addresses		Authors' Addresses
	Lenny Giuliano		Lenny Giuliano
	Juniper Networks		Juniper Networks
	2251 Corporate Park Drive		2251 Corporate Park Drive
	Herndon, VA 20171,		Herndon, VA 20171
	United States of America		United States of America
	Email: lenny@juniper.net		Email: lenny@juniper.net
	Chris Lenart		Chris Lenart
	Verizon		Verizon
	22001 Loudoun County Parkway		22001 Loudoun County Parkway
	Ashburn, VA 20147,		Ashburn, VA 20147
	United States of America		United States of America
	Email: chris.lenart@verizon.com		Email: chris.lenart@verizon.com
	Rich Adam		Rich Adam
	GEANT		GEANT
	City House		City House
	126-130 Hills Road		126-130 Hills Road
	Cambridge		Cambridge
	CB2 1PQ		CB2 1PQ
	United Kingdom		United Kingdom
	Email: richard.adam@geant.org		Email: richard.adam@geant.org
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