Computing-Aware Traffic Steering (CATS) Problem Statement, Use Cases, and Requirements
draft-ietf-cats-usecases-requirements-02
| Document | Type | Active Internet-Draft (cats WG) | |
|---|---|---|---|
| Authors | Kehan Yao , Dirk Trossen , Mohamed Boucadair , Luis M. Contreras , Hang Shi , Yizhou Li , Shuai Zhang , Qing An | ||
| Last updated | 2024-01-01 | ||
| Replaces | draft-yao-cats-ps-usecases | ||
| RFC stream | Internet Engineering Task Force (IETF) | ||
| Intended RFC status | (None) | ||
| Formats | |||
| Additional resources | Mailing list discussion | ||
| Stream | WG state | WG Document | |
| Document shepherd | (None) | ||
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| Send notices to | (None) |
draft-ietf-cats-usecases-requirements-02
cats K. Yao
Internet-Draft China Mobile
Intended status: Informational D. Trossen
Expires: 5 July 2024 Huawei Technologies
M. Boucadair
Orange
LM. Contreras
Telefonica
H. Shi
Y. Li
Huawei Technologies
S. Zhang
China Unicom
Q. An
Alibaba Group
2 January 2024
Computing-Aware Traffic Steering (CATS) Problem Statement, Use Cases,
and Requirements
draft-ietf-cats-usecases-requirements-02
Abstract
Distributed computing is a tool that service providers can use to
achieve better service response time and optimized energy
consumption. In such a distributed computing environment, providing
services by utilizing computing resources hosted in various computing
facilities aids support of services such as computationally intensive
and delay sensitive services. Ideally, compute services are balanced
across servers and network resources to enable higher throughput and
lower response times. To achieve this, the choice of server and
network resources should consider metrics that are oriented towards
compute capabilities and resources instead of simply dispatching the
service requests in a static way or optimizing solely on connectivity
metrics. The process of selecting servers or service instance
locations, and of directing traffic to them on chosen network
resources is called "Computing-Aware Traffic Steering" (CATS).
This document provides the problem statement and the typical
scenarios for CATS, which shows the necessity of considering more
factors when steering traffic to the appropriate computing resource
to best meet the customer's expectations and deliver the requested
service.
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Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
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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."
This Internet-Draft will expire on 5 July 2024.
Copyright Notice
Copyright (c) 2024 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents (https://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 Revised BSD License text as
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provided without warranty as described in the Revised BSD License.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Definition of Terms . . . . . . . . . . . . . . . . . . . . . 4
3. Problem Statement . . . . . . . . . . . . . . . . . . . . . . 6
3.1. Multi-deployment of Edge Sites and Service . . . . . . . 6
3.2. Traffic Steering among Edges Sites and Service
Instances . . . . . . . . . . . . . . . . . . . . . . . . 7
4. Use Cases . . . . . . . . . . . . . . . . . . . . . . . . . . 10
4.1. Computing-Aware AR or VR . . . . . . . . . . . . . . . . 11
4.2. Computing-Aware Intelligent Transportation . . . . . . . 14
4.3. Computing-Aware Digital Twin . . . . . . . . . . . . . . 15
4.4. Computing-Aware SD-WAN . . . . . . . . . . . . . . . . . 16
4.5. Computing-Aware AI Large Model Inference . . . . . . . . 18
5. Requirements . . . . . . . . . . . . . . . . . . . . . . . . 19
5.1. Support dynamic and effective selection among multiple
serivce instances . . . . . . . . . . . . . . . . . . . . 20
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5.2. Support Agreement on Metric Representation . . . . . . . 20
5.3. Support Moderate Metric Distributing . . . . . . . . . . 21
5.4. Support Alternative Definition and Use of Metrics . . . . 22
5.5. Support Instance Affinity . . . . . . . . . . . . . . . . 22
5.6. Preserve Communication Confidentiality . . . . . . . . . 24
6. Security Considerations . . . . . . . . . . . . . . . . . . . 24
7. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 25
8. Contributors . . . . . . . . . . . . . . . . . . . . . . . . 25
9. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 25
10. References . . . . . . . . . . . . . . . . . . . . . . . . . 25
10.1. Normative References . . . . . . . . . . . . . . . . . . 25
10.2. Informative References . . . . . . . . . . . . . . . . . 26
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 27
1. Introduction
Network and computing convergence has been evolving in the Internet
for considerable time. With Content Delivery Networks (CDNs)
'frontloading' access to many services, over-the-top service
provisioning has become a driving force for many services, such as
video, storage and many others. Network operators have extended
their capabilities by complementing their network infrastructure by
developing CDN capabilities, particularly in edge sites. In
addition, more computing resource are deployed at these edge sites as
well.
The reason of the fast development of this converged network/compute
infrastructure is user demand. On the one hand, users want the best
experience, e.g., expressed in low latency and high reliability, for
new emerging applications such as high-definition video, Augmented
Reality(AR)/Virtual Reality(VR), live broadcast and so on. On the
other hand, users want stable experience when moving to different
areas.
Generally, edge computing aims to provide better response times and
transfer rates compared to cloud computing, by moving the computing
towards the edge of a network. There are millions of home gateways,
thousands of base stations, and hundreds of central offices in a city
that could serve as compute-capable nodes to deliver a service. Note
that not all of these nodes would be considered as edge nodes in some
views of the network, but they can all provide computing resources to
enable a service.
That brings about the key problem of deploying and scheduling traffic
to the most suitable computing resource in order to meet the users'
service demand.
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Service providers often have their own service sites, many of which
have been enhanced to support computing services. A service instance
deployed at a single site might not provide sufficient capacity to
fully guarantee the quality of service required by a customer.
Especially at peak hours, computing resources at a single site can
not handle all the incoming service requests, leading to longer
response times or even dropping of requests experienced by clients.
Moreover, increasing the computing resources hosted at each location
to the potential maximum capacity is neither feasible nor
economically viable in many cases. Offloading computation intensive
processing to the user devices is neither acceptable, since it would
place huge pressure on local resources such as the battery and incur
some data privacy issues if the needed data for computation is not
provided locally.
Instead, the same service can be deployed at multiple sites for
better availability and scalability. Furthermore, it is desirable to
balance the load across all service instances to improve throughput.
For this, traffic needs to be steered to the 'best' service instance
according to information that may include current computing load,
where the notion of 'best' may highly depend on the application
demands.
This document describes sample usage scenarios that drive CATS
requirements and will help to identify candidate solution
architectures and solutions.
2. Definition of Terms
This document makes use of the following terms. The terminology
echoes what is in [I-D.ldbc-cats-framework]:
Client: An endpoint that is connected to a service provider network.
Computing-Aware Traffic Steering (CATS): A traffic engineering
approach [I-D.ietf-teas-rfc3272bis] that takes into account the
dynamic nature of computing resources and network state to optimize
service-specific traffic forwarding towards a given service contact
instance. Various relevant metrics may be used to enforce such
computing-aware traffic steering policies.
Service: An offering that is made available by a provider by
orchestrating a set of resources (networking, compute, storage,
etc.). Which and how these resources are solicited is part of the
service logic which is internal to the provider. For example,
these resources may be:
* Exposed by one or multiple processes (a.k.a. Service
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Functions (SFs) ). [RFC7665]
* Provided by virtual instances, physical, or a combination
thereof.
* Hosted within the same or distinct nodes.
* Hosted within the same or multiple service sites.
* Chained to provide a service using a variety of means.
How a service is structured is out of the scope of CATS.
The same service can be provided in many locations; each of them
constitutes a service instance.
Service identifier: An identifier representing a service, which the
clients use to access it.
Computing Service: An offering that is made available by a provider
by orchestrating a set of computing resources (without networking
resources).
Service instance: An instance of running resources according to a
given service logic. Many such instances can be enabled by a
provider. Instances that adhere to the same service logic provide
the same service. An instance is typically running in a service
site. Clients' requests are serviced by one of these instances.
Service site: A location that hosts the resources that are required
to offer a service. A service site may be a node or a set of
nodes. A CATS-serviced site is a service site that is connected to
a CATS-Forwarder.
Network Edge: The network edge is an architectural demarcation point
used to identify physical locations where the corporate network
connects to third-party networks.
Edge Computing: Edge computing is a computing pattern that moves
computing infrastructures, i.e, servers, away from centralized data
centers and instead places it close to the end users for low
latency communication.
Relations with network edge: edge computing infrastructures
connect to corporate network through a network edge entry/exit
point.
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Even though this document is not a protocol specification, it makes
use of upper case key words to define requirements unambiguously.
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
3.1. Multi-deployment of Edge Sites and Service
Since edge computing aims at a closer computing service based on the
shorter network path, there will be more than one edge site with the
same application in the city/province/state, a number of
representative cities have deployed multi-edge sites and the typical
applications, and there are more edge sites to be deployed in the
future. Before deploying edge sites, there are some factors that
need to be considered, such as:
o The exsiting infrastructure capacities, which could be updated to
edge sites, e.g. operators' machine room.
o The amount and frequency of computing resource that is needed.
o The network resource status linked to computing resource.
To improve the effectiveness of service deployment, the problem of
how to choose the optimal edge node on which to deploy services needs
to be solved. [I-D.contreras-alto-service-edge] introduces
considerations for how to deploy applications or functions to the
edge, such as the type of instance, optional storage extension,
optional hardware acceleration characteristics, and the compute
flavor of CPU/GPU, etc. More network and service factors may also be
considered, such as:
o Network and computing resource topology: The overall consideration
of network access, connectivity, path protection or redundancy, and
the location and overall distribution of computing resources in the
network, and the relative position within the network topology.
o Location: The number of users, the differentiation of service
types, and the number of connections requested by users, etc. For
edge nodes located in populous area with a large number of users and
service requests, service duplication could be deployed more than in
other areas.
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o Capacity of multiple edge nodes: Not only the capacity of a single
node, but also the total number of requests that can be processed by
the resource pool composed of multiple nodes.
o Service category: For example, whether the service is a multi-user
interaction, such as video conferencing, or games, or whether it just
resource acquisition, such as video viewing. ALTO [RFC7285] can help
to obtain one or more of the above pieces of information, so as to
provide suggestions or formulate principles and strategies for
service deployment.
This information could be collected periodically, and could record
the total consumption of computing resources, or the total number of
sessions accessed. This would indicate whether additional service
instances need to be deployed. Unlike the scheduling of service
requests, service deployment should follow the principle of proximity
to place new service instances near to customer sites that will
request them. If the resources are insufficient to support new
instances, the operator can be informed to increase the hardware
resources.
In general, the choice of where to locate service instances and when
to create new ones in order to provide the right levels of resource
to support user demands is important in building a network that
supports computing services. However, those aspects are out of scope
for CATS and are left for consideration in another document.
3.2. Traffic Steering among Edges Sites and Service Instances
This section describes how existing edge computing systems do not
provide all of the support needed for real-time or near-real-time
services, and how it is necessary to steer traffic to different sites
considering mobility of people, different time slots, events, server
loads, and network capabilities, etc.
In edge computing, the computing resources and network resources are
considered when deploying edge sites and services. Traffic is
steered to an edge site that is "closest" or to one of a few "close"
sites using load-balancing. But the "closest" site is not always the
"best" as the status of computing resources and of the network may
vary as follows:
o Closest site may not have enough resource, the load may dynamically
change.
o Closest site may not have related resource, heterogeneous hardware
in different sites.
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o The network path to the closest site might not provide the
necessary network characteristics, such as low latency or high
throughput.
To address these issues some enhancements are needed to steer traffic
to sites that can support the requested services.
We assume that clients access one or more services with an objective
to meet a desired user experience. Each participating service may be
realized at one or more places in the network (called, service
instances). Such service instances are instantiated and deployed as
part of the overall service deployment process, e.g., using existing
orchestration frameworks, within so-called edge sites, which in turn
are reachable through a network infrastructure via an edge router.
When a client issues a service request for a required service, the
request is steered to one of the available service instances. Each
service instance may act as a client towards another service, thereby
seeing its own outbound traffic steered to a suitable service
instance of the request service and so on, achieving service
composition and chaining as a result.
The aforementioned selection of one of candidate service instances is
done using traffic steering methods, where the steering decision may
take into account pre-planned policies (assignment of certain clients
to certain service instances), realize shortest-path to the 'closest'
service instance, or utilize more complex and possibly dynamic metric
information, such as load of service instances, latency experienced
or similar, for a more dynamic selection of a suitable service
instance.
It is important to note that clients may move. This means that the
service instance that was "best" at one moment might no longer be
best when a new service request is issued. This creates a (physical)
dynamicity that will need to be catered for in addition to the
changes in server and network load.
Figure 1 shows a common way to deploy edge sites in the metro. There
is an edge data center for metro area which has high computing
resource and provides the service to more User Equipments(UEs) at the
working time. Because more office buildings are in the metro area.
And there are also some remote edge sites which have limited
computing resource and provide the service to the UEs closed to them.
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Applications to meet service demands could be deployed in both the
edge data center in metro area and the remote edge sites. In this
case, the service request and the resource are matched well. Some
potential traffic steering may be needed just for special service
request or some small scheduling demand.
+----------------+ +---+ +------------+
+----------------+ |- - |UE1| +------------+ |
| +-----------+ | | +---+ +--| Edge | |
| |Edge server| | | +---+ +- - -|PE| | |
| +-----------+ | |- - |UE2| | +--| Site 1 |-+
| +-----------+ | | +---+ +------------+
| |Edge server| | | ... | |
| +-----------+ | +--+ Potential +---+ +---+
| +-----------+ | |PE|- - - - - - -+ |UEa| |UEb|
| |Edge server| | +--+ Steering +---+ +---+
| +-----------+ | | +---+ | |
| +-----------+ | |- - |UE3| +------------+
| | ... ... | | | +---+ | +------------+ |
| +-----------+ | | ... +--| Edge | |
| | | +---+ +- - -|PE| | |
|Edge data center|-+- - |UEn| +--| Site 2 |-+
+----------------+ +---+ +------------+
High computing resource Limited computing resource
and more UE at metro area and less UE at remote area
Figure 1: Common Deployment of Edge Sites
Figure 2 shows that during non-working hours, for example at weekend
or daily night, more UEs move to the remote area that are close to
their house or for some weekend events. So there will be more
service request at remote but with limited computing resource, while
the rich computing resource might not be used with less UE in the
metro area. It is possible for many people to request services at
the remote area, but with the limited computing resource, moreover,
as the people move from the metro area to the remote area, the edge
sites that serve common services will also change, so it may be
necessary to steer some traffic back to the metro data center.
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+----------------+ +------------+
+----------------+ | +------------+ |
| +-----------+ | | Steering traffic +--| Edge | |
| |Edge server| | | +-----------|PE| | |
| +-----------+ | | +---+ | +--| Site 1 |-+
| +-----------+ | |- - |UEa| | +----+----+-+----------+
| |Edge server| | | +---+ | | | |
| +-----------+ | +--+ | +---+ +---+ +---+ +---+ +---+
| +-----------+ | |PE|-------+ |UE1| |UE2| |UE3| |...| |UEn|
| |Edge server| | +--+ | +---+ +---+ +---+ +---+ +---+
| +-----------+ | | +---+ | | |
| +-----------+ | |- - |UEb| | +-----+-----+------+
| | ... ... | | | +---+ | +------------+ |
| +-----------+ | | | +--| Edge | |
| | | +-----------|PE| | |
|Edge data center|-+ Steering traffic +--| Site 2 |-+
+----------------+ +------------+
High computing resource Limited computing resource
and less UE at metro area and more UE at remote area
Figure 2: Steering Traffic among Edge Sites
There will also be the common variable of network and computing
resources, for someone who is not moving but get a poor latency
sometime. Because of other UEs moving, a large number of request for
temporary events such as vocal concert, shopping festival and so on,
and there will also be the normal change of the network and computing
resource status. So for some fixed UEs, it is also expected to steer
the traffic to appropriate sites dynamicity.
Those problems indicate that traffic needs to be steered among
different edge sites, because of the mobility of the UE and the
common variable of network and computing resources. Moreover, some
use cases in the following section require both low latency and high
computing resource usage or specific computing hardware capabilities
(such as local GPU); hence joint optimization of network and
computing resource is needed to guarantee the Quality of
Experience(QoE).
4. Use Cases
This section presents a non-exhaustive set of use cases which would
benefit from the dynamic selection of service instances and the
steering of traffic to those service instances.
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4.1. Computing-Aware AR or VR
Cloud VR/AR services are used in some exhibitions, scenic spots, and
celebration ceremonies. In the future, they might be used in more
applications, such as industrial internet, medical industry, and meta
verse.
Cloud VR/AR introduces the concept of cloud computing to the
rendering of audiovisual assets in such applications. Here, the edge
cloud helps encode/decode and render content. The end device usually
only uploads posture or control information to the edge and then VR/
AR contents are rendered in the edge cloud. The video and audio
outputs generated from the edge cloud are encoded, compressed, and
transmitted back to the end device or further transmitted to central
data center via high bandwidth networks.
Edge sites may use CPU or GPU for encode/decode. GPU usually has
better performance but CPU is simpler and more straightforward to use
as well as possibly more widespread in deployment. Available
remaining resources determines if a service instance can be started.
The instance's CPU, GPU and memory utilization has a high impact on
the processing delay on encoding, decoding and rendering. At the
same time, the network path quality to the edge site is a key for
user experience of quality of audio/ video and input command response
times.
A Cloud VR service, such as a mobile gaming service, brings
challenging requirements to both network and computing so that the
edge node to serve a service request has to be carefully selected to
make sure it has sufficient computing resource and good network path.
For example, for an entry-level cloud VR (panoramic 8K 2D video) with
110-degree Field of View (FOV) transmission, the typical network
requirements are bandwidth 40Mbps, 20ms for motion-to-photon latency,
packet loss rate is 2.4E-5; the typical computing requirements are 8K
H.265 real-time decoding, 2K H.264 real-time encoding. We can
further divide the 20ms latency budget into:
(i) sensor sampling delay(client), which is considered imperceptible
by users is less than 1.5ms including an extra 0.5ms for
digitalization and end device processing.
(ii) display refresh delay(client), which take 7.9ms based on the
144Hz display refreshing rate and 1ms extra delay to light up.
(iii) image/frame rendering delay(server), which could be reduced to
5.5ms.
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(iv) round trip network delay(network), which should be bounded to
20-1.5-5.5-7.9 = 5.1ms.
So the the budgets for server(computing) delay and network delay are
almost equivalent, which make sense to consider both of the delay for
computing and network. And it can't meet the total delay
requirements or find the best choice by either optimize the network
or computing resource.
Based on the analysis, here are some further assumption as figure 3
shows, the client could request any service instance among 3 edge
sites. The delay of client could be same, and the differences of
different edge sites and corresponding network path has different
delays:
o Edge site 1: The computing delay=4ms based on a light load, and the
corresponding network delay=9ms based on a heavy traffic.
o Edge site 2: The computing delay=10ms based on a heavy load, and
the corresponding network delay=4ms based on a light traffic.
o Edge site 3: The edge site 3's computing delay=5ms based on a
normal load, and the corresponding network delay=5ms based on a
normal traffic.
In this case, we can't get a optimal network and computing total
delay if choose the resource only based on either of computing or
network status:
o If choosing the edge site based on the best computing delay it will
be the edge site 1, the E2E delay=22.4ms.
o If choosing the edge site based on the best network delay it will
be the edge site 2, the E2E delay=23.4ms.
o If choosing the edge site based on both of the status it will be
the edge site 3, the E2E delay=19.4ms.
So, the best choice to ensure the E2E delay is edge site 3, which is
19.4ms and is less than 20ms. The differences of the E2E delay is
only 3~4ms among the three, but some of them will meet the
application demand while some doesn't.
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The conclusion is that it requires to dynamically steer traffic to
the appropriate edge to meet the E2E delay requirements considering
both network and computing resource status. Moreover, the computing
resources have a big difference in different edges, and the "closest
site" may be good for latency but lacks GPU support and should
therefore not be chosen.
Light Load Heavy Load Normal load
+------------+ +------------+ +------------+
| Edge | | Edge | | Edge |
| Site 1 | | Site 2 | | Site 3 |
+-----+------+ +------+-----+ +------+-----+
computing|delay(4ms) | computing|delay(5ms)
| computing|delay(10ms) |
+----+-----+ +-----+----+ +-----+----+
| Egress | | Egress | | Egress |
| Router 1 | | Router 2 | | Router 3 |
+----+-----+ +-----+----+ +-----+----+
newtork|delay(9ms) newtork|delay(4ms) newtork|delay(5ms)
| | |
| +--------+--------+ |
+-----------| Infrastructure |-----------+
+--------+--------+
|
+----+----+
| Ingress |
+---------------| Router |--------------+
| +----+----+ |
| | |
+--+--+ +--+---+ +---+--+
+------+| +------+ | +------+ |
|Client|+ |Client|-+ |Client|-+
+------+ +------+ +------+
client delay=1.5+7.9=9.4ms
Figure 3: Computing-Aware AR or VR
Furthermore, specific techniques may be employed to divide the
overall rendering into base assets that are common across a number of
clients participating in the service, while the client-specific input
data is being utilized to render additional assets. When being
delivered to the client, those two assets are being combined into the
overall content being consumed by the client. The requirements for
sending the client input data as well as the requests for the base
assets may be different in terms of which service instances may serve
the request, where base assets may be served from any nearby service
instance (since those base assets may be served without requiring
cross-request state being maintained), while the client-specific
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input data is being processed by a stateful service instance that
changes, if at all, only slowly over time due to the stickiness of
the service that is being created by the client-specific data. Other
splits of rendering and input tasks can be found in[TR22.874] for
further reading.
When it comes to the service instances themselves, those may be
instantiated on-demand, e.g., driven by network or client demand
metrics, while resources may also be released, e.g., after an idle
timeout, to free up resources for other services. Depending on the
utilized node technologies, the lifetime of such "function as a
service" may range from many minutes down to millisecond scale.
Therefore computing resources across participating edges exhibit a
distributed (in terms of locations) as well as dynamic (in terms of
resource availability) nature. In order to achieve a satisfying
service quality to end users, a service request will need to be sent
to and served by an edge with sufficient computing resource and a
good network path.
4.2. Computing-Aware Intelligent Transportation
For the convenience of transportation, more video capture devices are
required to be deployed as urban infrastructure, and the better video
quality is also required to facilitate the content analysis.
Therefore, the transmission capacity of the network will need to be
further increased, and the collected video data need to be further
processed, such as for pedestrian face recognition, vehicle moving
track recognition, and prediction. This, in turn, also impacts the
requirements for the video processing capacity of computing nodes.
In auxiliary driving scenarios, to help overcome the non-line-of-
sight problem due to blind spot or obstacles, the edge node can
collect comprehensive road and traffic information around the vehicle
location and perform data processing, and then vehicles with high
security risk can be warned accordingly, improving driving safety in
complicated road conditions, like at intersections. This scenario is
also called "Electronic Horizon", as explained in[HORITA]. For
instance, video image information captured by, e.g., an in-car,
camera is transmitted to the nearest edge node for processing. The
notion of sending the request to the "nearest" edge node is important
for being able to collate the video information of "nearby" cars,
using, for instance, relative location information. Furthermore,
data privacy may lead to the requirement to process the data as close
to the source as possible to limit data spread across too many
network components in the network.
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Nevertheless, load at specific "closest" nodes may greatly vary,
leading to the possibility for the closest edge node becoming
overloaded, leading to a higher response time and therefore a delay
in responding to the auxiliary driving request with the possibility
of traffic delays or even traffic accidents occurring as a result.
Hence, in such cases, delay-insensitive services such as in-vehicle
entertainment should be dispatched to other light loaded nodes
instead of local edge nodes, so that the delay-sensitive service is
preferentially processed locally to ensure the service availability
and user experience.
In video recognition scenarios, when the number of waiting people and
vehicles increases, more computing resources are needed to process
the video content. For rush hour traffic congestion and weekend
personnel flow from the edge of a city to the city center, efficient
network and computing capacity scheduling is also required. Those
would cause the overload of the nearest edge sites if there is no
extra method used, and some of the service request flow might be
steered to others edge site except the nearest one.
4.3. Computing-Aware Digital Twin
A number of industry associations, such as the Industrial Digital
Twin Association or the Digital Twin Consortium
(https://www.digitaltwinconsortium.org/), have been founded to
promote the concept of the Digital Twin (DT) for a number of use case
areas, such as smart cities, transportation, industrial control,
among others. The core concept of the DT is the "administrative
shell" [Industry4.0], which serves as a digital representation of the
information and technical functionality pertaining to the "assets"
(such as an industrial machinery, a transportation vehicle, an object
in a smart city or others) that is intended to be managed,
controlled, and actuated.
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As an example for industrial control, the programmable logic
controller (PLC) may be virtualized and the functionality aggregated
across a number of physical assets into a single administrative shell
for the purpose of managing those assets. PLCs may be virtualized in
order to move the PLC capabilities from the physical assets to the
edge cloud. Several PLC instances may exist to enable load balancing
and fail-over capabilities, while also enabling physical mobility of
the asset and the connection to a suitable "nearby" PLC instance.
With this, traffic dynamicity may be similar to that observed in the
connected car scenario in the previous sub-section. Crucial here is
high availability and bounded latency since a failure of the
(overall) PLC functionality may lead to a production line stop, while
boundary violations of the latency may lead to loosing
synchronization with other processes and, ultimately, to production
faults, tool failures or similar.
Particular attention in Digital Twin scenarios is given to the
problem of data storage. Here, decentralization, not only driven by
the scenario (such as outlined in the connected car scenario for
cases of localized reasoning over data originating from driving
vehicles) but also through proposed platform solutions, such as those
in [GAIA-X], plays an important role. With decentralization,
endpoint relations between client and (storage) service instances may
frequently change as a result.
4.4. Computing-Aware SD-WAN
SD-WAN provides organizations or enterprises with centralized control
over multiple sites which are network endpoints including branch
offices, headquarters, data centers, clouds, and more. A enterprise
may deploy their services and applications in different locations to
achieve optimal performance. The traffic sent by a host will take
the shortest WAN path to the closest server. However, the closet
server may not be the best choice with lowest cost of network and
computing resources for the host. If the path computation element
can consider the computing dimension information in path computation,
the best path with lowest cost can be provided.
The computing related information can be the number of vCPUs of the
VM running the application/services, CPU utilization rate, usage of
memory, etc.
The SD-WAN can be aware of the computing resource of applications
deployed in the multiple sites and can perform the routing policy
according to the information is defined as the computing-aware SD-
WAN.
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Many enterprises are performing the cloud migration to migrate the
applications from data centers to the clouds, including public,
private, and hybrid clouds. The clouds resources can be from the
same provider or multiple cloud providers which have some benefits
including disaster recovery, load balancing, avoiding vendor lock-in.
In such cloudification deployments SD-WAN provides enterprises with
centralized control over Customer-Premises Equipments(CPEs) in branch
offices and the cloudified CPEs(vCPEs) in the clouds.The CPEs connect
the clients in branch offices and the application servers in clouds.
The same application server in different clouds is called an
application instance. Different application instances have different
computing resource.
SD-WAN is aware of the computing resource of applications deployed in
the clouds by vCPEs, and selects the application instance for the
client to visit according to computing power and the network state of
WAN.
Figure 4 below illustrates Computing-aware SD-WAN for Enterprise
Cloudification.
+---------------+
+-------+ +----------+ | Cloud1 |
|Client1| /---------| WAN1 |------| vCPE1 APP1 |
+-------+ / +----------+ +---------------+
+-------+ +-------+
|Client2| ------ | CPE |
+-------+ +-------+ +---------------+
+-------+ \ +----------+ | Cloud2 |
|Client3| \---------| WAN2 |------| vCPE2 APP1 |
+-------+ +----------+ +---------------+
Figure 4: Illustration of Computing-aware SD-WAN for Enterprise
Cloudification
The current computing load status of the application APP1 in cloud1
and cloud2 is as follows: each application uses 6 vCPUs. The load of
application in cloud1 is 50%. The load of application in cloud2 is
20%. The computing resource of APP1 are collected by vCPE1 and vCPE2
respectively. Client1 and Client2 are visiting APP1 in cloud1. WAN1
and WAN2 have the same network states. Considering lightly loaded
application SD-WAN selects APP1 in cloud2 for the client3 in branch
office. The traffic of client3 follows the path: Client3 -> CPE ->
WAN1 -> Cloud2 vCPE1 -> Cloud2 APP1
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4.5. Computing-Aware AI Large Model Inference
AI(Artificial Intelligence) large model refers to models that are
characterized by their large size, high complexity, and high
computational requirements. AI large models have become increasingly
important in various fields, such as natural language processing for
text classification, computer vision for image classification and
object detection, and speech recognition.
AI large model contains two key phases: training and inference.
Training refers to the process of developing an AI model by feeding
it with large amounts of data and optimizing it to learn and improve
its performance. Training has high demand on computing and memory
resource, so that training is usually deployed in large central data
centers. On the other hand, inference is the process of using the
trained AI model to make predictions or decisions based on new input
data. Compared to traing, the AI Inference does not consume large
amout of computing resources,and it is usually deployed at edge sites
and end devices for real time and dynamic service response.
Figure 5 shows the cloud-edge-device co-inference deployment. Single
site deployment of the model can not provide enough compute resources
and is not sufficient for fullfilling some AI Inference work. The
cloud-edge-device co-inference can not only guarantee the compute
resouces but also achieve low latency as part of AI inference tasks
is deployed near clients or even within client devices. When
handling AI inference tasks, if traffic load between clients and edge
sites is high or edge resource are overloaded, the response of
inference may not be accepted by services. And CATS is needed to
ensure the QoS of AI inference
There are different types of deployments for cloud-edge-device co-
inference. Depending on applications and compute resources. Models
can be deployed in edge sites only or in both cloud and edge sites.
More specifically, some pruned models can be deployed in end devices
for compute offloading and low latency response. In all of the cases
above, the problem of steering the traffic to different edge sites
fits in the scope of CATS.
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The same trained model will be deployed in each edge sites so as to
provide undifferenciated inference service. Service selection across
different edge sites is for low latency service response just like
use cases mentioned in other sections above. Moreover, Specific
compute resources like GPUs which are most suitable for AI inference
are provided at each edge sites, and relevant metrics should be
collected and distributed to the network for better traffic steering
decision making. Generalized compute resources like CPUs can also
finish AI inference, but they are less efficient and power saving
than GPUs.
Cloud-Edge-Device Co-Inference
+------------------------------------------------------+
| |
| Cloud |
| |
| +------------------+ |
| | Large Model | |
| +------------------+ |
+--------------------------+---------------------------+
|
| Inference
+----------------------------+-----------------------------+
| +--------------+ +--------------+ +--------------+ |
| | Edge | | Edge | | Edge | |
| | +----------+ | | +----------+ | | +----------+ | |
| | | | | | | | | | | | | |
| | | Models | | | | Models | | | | Models | | |
| | +----------+ | | +----------+ | | +----------+ | |
| +--------------+ +--------------+ +--------------+ |
+----------+-----------------+---------------+-------------+
| | |
| | |
+----+-----+ +----+-----+ +----+-----+
| Device | | Device | ... | Device |
| +------+ | | +------+ | | +------+ |
| |Pruned| | | |Pruned| | | |Pruned| |
| |Model | | | |Model | | | |Model | |
| +------+ | | +------+ | | +------+ |
+----------+ +----------+ +----------+
Inference Inference Inference
Figure 5: Illustration of Computing-aware AI large model inference
5. Requirements
In the following, we outline the requirements for the CATS system to
overcome the observed problems in the realization of the use cases
above.
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5.1. Support dynamic and effective selection among multiple serivce
instances
The basic requirement of CATS is to support the dynamic access to
different service instances residing in multiple computing sites and
then being aware of their status, which is also the fundamental model
to enable the traffic steering and to further optimize the network
and computing services. A unique service identifier is used by all
the service instances for a specific service no matter which edge
site an instance may attach to. The mapping of this service
identifier to a network locator makes sure the data packet CATS
potentially reach any of the service instances deployed in various
edge sites.
Moreover, according to CATS use cases, some applications require E2E
low latency, which warrants a quick mapping of the service identifier
to the network locator. This leads to naturally the in-band methods,
involving the consideration of using metrics that are oriented
towards compute capabilities and resources, and their corelation with
services. Therefore, a desirable system
R1: MUST provide a discovery and resolving methodology for the
mapping of a service identifier to a specific address.
R2: MUST provide an mapping methods for further quickly selecting the
service instance.
R3: SHOULD provide a timeout limitation for selecting the service
instance.
R4: MUST provide a method to determine the availability of a service
instance.
R5: MUST provide a mechanism for solving the service contention
problem when multiple service instances with the same service
indentifier are all available to provide computing services.
5.2. Support Agreement on Metric Representation
Computing metrics can have many different semantics, particularly for
being service-specific. Even the notion of a "computing load" metric
could be represented in many different ways. Such representation may
entail information on the semantics of the metric or it may be purely
one or more semantic- free numerals. Agreement of the chosen
representation among all service and network elements participating
in the service instance selection decision is important. Therefore,
a desirable system
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R6: MUST agree on using metrics that are oriented towards compute
capabilities and resources and their representation among service
elements in the participating edges.
R7: MUST include network metrics.
5.3. Support Moderate Metric Distributing
Network path costs in the current routing system usually do not
change very frequently. Network traffic engineering metrics (such as
available bandwidth) may change more frequently as traffic demands
fluctuate, but distribution of these changes is normally damped so
that only significant changes cause routing protocol messages.
However, metrics that are oriented towards compute capabilities and
resources in general can be highly dynamic, e.g., changing rapidly
with the number of sessions, the CPU/GPU utilization and the memory
consumption, etc. It has to be determined at what interval or based
on what events such information needs to be distributed. Overly
frequent distribution with more accurate synchronization may result
in unnecessary overhead in terms of signaling.
Moreover, depending on the service related decision logic, one or
more metrics need to be conveyed in a CATS domain. The problem to be
addressed here may be the frequency of such conveyance, thanks to the
comprehensive load that a signaling process may add to the overall
network traffic. While existing routing protocols may serve as a
baseline for signaling metrics, other means to convey the metrics can
equally be considered and even be realized. Specifically, a
desirable system
R8: MUST provide mechanisms for metric collection.
Collecting metrics from all of the services instances may incur much
overhead for the decision maker, and thus hierarchical metric
collection is needed. That is,
R9: SHOULD provide mechanisms to aggregate the metrics.
CATS components do not need to be aware of how metrics are collected
behind the aggregator.
R10: MUST provide mechanisms to distribute the metrics.
R11: MUST realize means for rate control for distributing of metrics.
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5.4. Support Alternative Definition and Use of Metrics
Considering computing resources assigned to a service instance on a
server, which might be related to some critical metrics like the
processing delay, is crucial in addition to the network delay in some
cases. Therefore, the CATS components might use both the network and
computing metrics for service instance selection. For this reason:
R12: a computing semantic model SHOULD be defined for the mapping
selection.
We recognize that different network nodes, e.g., routers, switches,
etc., may have diversified capabilities even in the same routing
domain, let alone in different administrative domains. So, metrics
that are oriented towards compute capabilities and resources that
have been adopted by some nodes may not be supported by others,
either due to technical reasons, administrative reasons, or something
else. There exist scenarios in which a node supporting service-
specific metrics might prefer some type of metrics to
others[TR22.874]. Of course, specific metrics might not be utilized
at all in other scenarios. Hence:
R13: In addition to common metrics that are agreed by all CATS
components like processing delay, there SHOULD be some other ways for
metrics definition, which is used for the selection of specific
service instance.
Therefore, a desirable system
R14: MUST set up metric information that can be understood by CATS
components.
For metrics that CATS components do not understand or support, CATS
components will ignore them.
5.5. Support Instance Affinity
In the CATS system, a service may be provided by one or more service
instances that would be deployed at different locations in the
network. Each instance provides equivalent service functionality to
their respective clients. The decision logic of the instance
selection are subject to the normal packet level communication and
packets are forwarded based on the operating status of both network
and computing resources. This resource status will likely change
over time, leading to individual packets potentially being sent to
different network locations, possibly segmenting individual service
transactions and breaking service-level semantics. Moreover, when a
client moves, the access point might change and successively lead to
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the same result of the change of service instance. If execution
changes from one (e.g., virtualized) service instance to another,
state/context needs transfer to another. Such required transfer of
state/context makes it desirable to have instance affinity as the
default, removing the need for explicit context transfer, while also
supporting an explicit state/context transfer (e.g., when metrics
change significantly). So in those situations:
R15: Instance affinity MUST be maintained when state information is
needed.
The nature of this affinity is highly dependent on the nature of the
specific service, which could be seen as a 'instance affinity' to
represent the relationship. The minimal affinity of a single request
represents a stateless service, where each service request may be
responded to without any state being held at the service instance for
fulfilling the request.
Providing any necessary information/state in-band as part of the
service request, e.g., in the form of a multi-form body in an HTTP
request or through the URL provided as part of the request, is one
way to achieve such stateless nature.
Alternatively, the affinity to a particular service instance may span
more than one request, as in the AR/VR use case, where previous
client input is needed to render subsequent frames.
However, a client, e.g., a mobile UE, may have many applications
running. If all, or majority, of the applications request the CATS-
based services, then the runtime states that need to be created and
accordingly maintained would require high granularity. In the
extreme scenario, this granular requirement could reach the level of
per-UE per-APP per-(sub)flow with regard to a service instance.
Evidently, these fine-granular runtime states can potentially place a
heavy burden on network devices if they have to dynamically create
and maintain them. On the other hand, it is not appropriate either
to place the state-keeping task on clients themselves.
Besides, there might be the case that UE moves to a new (access)
network or the service instance is migrated to another cloud, which
cause the unreachable or inconvenient of the original service
instance. So the UE and service instance mobility also need to be
considered.
Therefore, a desirable system
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R16: MUST maintain instance affinity which MAY span one or more
service requests, i.e., all the packets from the same application-
level flow MUST go to the same service instance unless the original
service instance is unreachable
R17: MUST avoid keeping fine runtime-state granularity in network
nodes for providing instance affinity.
R18: MUST provide mechanisms to minimize client side states in order
to achieve the instance affinity.
R19: SHOULD support the UE and service instance mobility.
5.6. Preserve Communication Confidentiality
Exposing the information of computing resources to the network may
lead to the leakage of computing domain and application privacy. In
order to prevent it, it need to consider the methods to process the
sensitive information related to computing domain. For instance,
using general anonymous methods, including hiding the key information
representing the identification of devices, or using an index to
represent the service level of computing resources, or using
customized information exposure strategies according to specific
application requirements or network scheduling requirements. At the
same time, when anonymity is achieved, it is also necessary to
consider whether the computing information exposed in the network can
help make full use of traffic steering. Therefore, a CATS system
R20: MUST preserve the confidentiality of the communication relation
between user and service provider by minimizing the exposure of user-
relevant information according to user needs.
6. Security Considerations
CATS decision making process is deeply related to computing and
network status as well as some service information. Some security
issues need to be considered when designing CATS system.
Service data sometimes needs to be moved among different edge sites
to maintain service consistency and availability. Therefore:
R21: service data MUST be protected from interception.
The act of making compute requests may reveal the nature of user's
activities, so that:
R22: the nature of user's activities SHOULD be hidden as much as
possible.
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The behavior of the network can be adversely affected by modifying or
interfering with advertisements of computing resource availability.
Such attacks could deprive users' of the services they desires, and
might be used to divert traffic to interception points. Therefore,
R23: secure advertisements are REQUIRED to prevent rogue nodes from
participating in the network.
7. IANA Considerations
This document makes no requests for IANA action.
8. Contributors
The following people have substantially contributed to this document:
Peter Willis
pjw7904@rjt.edu
Philip Eardley
philip.eardley@googlemail.com
Tianji Jiang
China Mobile
tianjijiang@chinamobile.com
Markus Amend
Deutsche Telekom
Markus.Amend@telekom.de
Guangping Huang
ZTE
huang.guangping@zte.com.cn
Dongyu Yuan
ZTE
yuan.dongyu@zte.com.cn
9. Acknowledgements
The author would like to thank Adrian Farrel, Peng Liu, Luigi
IANNONE, Christian Jacquenet and Yuexia Fu for their valuable
suggestions to this document.
10. References
10.1. Normative References
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[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>.
[RFC7285] Alimi, R., Ed., Penno, R., Ed., Yang, Y., Ed., Kiesel, S.,
Previdi, S., Roome, W., Shalunov, S., and R. Woundy,
"Application-Layer Traffic Optimization (ALTO) Protocol",
RFC 7285, DOI 10.17487/RFC7285, September 2014,
<https://www.rfc-editor.org/info/rfc7285>.
[RFC7665] Halpern, J., Ed. and C. Pignataro, Ed., "Service Function
Chaining (SFC) Architecture", RFC 7665,
DOI 10.17487/RFC7665, October 2015,
<https://www.rfc-editor.org/info/rfc7665>.
[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>.
10.2. Informative References
[I-D.ietf-teas-rfc3272bis]
Farrel, A., "Overview and Principles of Internet Traffic
Engineering", Work in Progress, Internet-Draft, draft-
ietf-teas-rfc3272bis-27, 12 August 2023,
<https://datatracker.ietf.org/doc/html/draft-ietf-teas-
rfc3272bis-27>.
[I-D.ldbc-cats-framework]
Li, C., Du, Z., Boucadair, M., Contreras, L. M., Drake,
J., Huang, D., and G. S. Mishra, "A Framework for
Computing-Aware Traffic Steering (CATS)", Work in
Progress, Internet-Draft, draft-ldbc-cats-framework-04, 8
December 2023, <https://datatracker.ietf.org/doc/html/
draft-ldbc-cats-framework-04>.
[I-D.contreras-alto-service-edge]
Contreras, L. M., Randriamasy, S., Ros-Giralt, J., Perez,
D. A. L., and C. E. Rothenberg, "Use of ALTO for
Determining Service Edge", Work in Progress, Internet-
Draft, draft-contreras-alto-service-edge-10, 13 October
2023, <https://datatracker.ietf.org/doc/html/draft-
contreras-alto-service-edge-10>.
[TR22.874] 3GPP, "Study on traffic characteristics and performance
requirements for AI/ML model transfer in 5GS (Release
18)", 2021.
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[HORITA] Horita, Y., "Extended electronic horizon for automated
driving", Proceedings of 14th International Conference on
ITS Telecommunications (ITST)", 2015.
[Industry4.0]
Industry4.0, "Details of the Asset Administration Shell,
Part 1 & Part 2", 2020.
[GAIA-X] Gaia-X, ""GAIA-X: A Federated Data Infrastructure for
Europe"", 2021.
Authors' Addresses
Kehan Yao
China Mobile
Email: yaokehan@chinamobile.com
Dirk Trossen
Huawei Technologies
Email: dirk.trossen@huawei.com
Mohamed Boucadair
Orange
Email: mohamed.boucadair@orange.com
Luis M. Contreras
Telefonica
Email: luismiguel.contrerasmurillo@telefonica.com
Hang Shi
Huawei Technologies
Email: shihang9@huawei.com
Yizhou Li
Huawei Technologies
Email: liyizhou@huawei.com
Shuai Zhang
China Unicom
Email: zhangs366@chinaunicom.cn
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Qing An
Alibaba Group
Email: anqing.aq@alibaba-inc.com
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