Joint Exposure of Network and Compute Information for Infrastructure-Aware Service Deployment

4.1. Distributed AI Workloads

Generative AI is a technological feat that opens up many applications such as holding conversations, generating art, developing a research paper, or writing software, among many others. Yet this innovation comes with a high cost in terms of processing and power consumption. While data centers are already running at capacity, it is projected that transitioning current search engine queries to leverage generative AI will increase costs by 10 times compared to traditional search methods [DC-AI-COST]. As (1) computing nodes (CPUs, GPUs, and NPUs) are deployed to build the edge cloud leveraging technologies like 5G and (2) with billions of mobile user devices globally providing a large untapped computational platform, shifting part of the processing from the cloud to the edge becomes a viable and necessary step towards enabling the AI-transition. There are at least four drivers supporting this trend:¶

• Computational and energy savings: Due to savings from not needing large-scale cooling systems and the high performance-per-watt efficiency of the edge devices, some workloads can run at the edge at a lower computational and energy cost [EDGE-ENERGY], especially when considering not only processing but also data transport.¶

• Latency: For applications such as driverless vehicles which require real-time inference at very low latency, running at the edge is necessary.¶

• Reliability and performance: Peaks in cloud demand for generative AI queries can create large queues and latency, and in some cases even lead to denial of service. Further, limited or no connectivity generally requires running the workloads at the edge.¶

• Privacy, security, and personalization: A "private mode" allows users to strictly utilize on-device (or near-the-device) AI to enter sensitive prompts to chatbots, such as health questions or confidential ideas.¶

These drivers lead to a distributed computational model that is hybrid: Some AI workloads will fully run in the cloud, some will fully run in the edge, and some will run both in the edge and in the cloud. Being able to efficiently run these workloads in this hybrid, distributed, cloud-edge environment is necessary given the aforementioned massive energy and computational costs. To make optimized service and workload placement decisions, information about both the compute and communication resources available in the network is necessary too.¶

Consider as an example a large language model (LLM) used to generate text and hold intelligent conversations. LLMs produce a single token per inference, where a token is a set of characters forming words or fractions of words. Pipelining and parallelization techniques are used to optimize inference, but this means that a model like GPT-3 could potentially go through all 175 billion parameters that are part of it to generate a single word. To efficiently run these computational-intensive workloads, it is necessary to know the availability of compute resources in the distributed system. Suppose that a user is driving a car while conversing with an AI model. The model can run inference on a variety of compute nodes, ordered from lower to higher compute power as follows: (1) the user's phone, (2) the computer in the car, (3) the 5G edge cloud, and (4) the datacenter cloud. Correspondingly, the system can deploy four different models with different levels of accuracy and compute requirements. The simplest model with the least parameters can run in the phone, requiring less compute power but yielding lower accuracy. Three other models ordered in increasing value of accuracy and computational complexity can run in the car, the edge, and the cloud. The application can identify the right trade-off between accuracy and computational cost, combined with metrics of communication bandwidth and latency, to make the right decision on which of the four models to use for every inference request. Note that this is similar to the resolution/bandwidth trade-off commonly found in the image encoding problem, where an image can be encoded and transmitted at different levels of resolution depending on the available bandwidth in the communication channel. In the case of AI inference, however, not only bandwidth is a scarce resource, but also compute.¶

4.2. Open Abstraction for Edge Computing

Modern applications such as AR/VR, V2X, or IoT, require bringing compute closer to the edge in order to meet strict bandwidth, latency, and jitter requirements. While this deployment process resembles the path taken by the main cloud providers (notably, AWS, Facebook, Google and Microsoft) to deploy their large-scale datacenters, the edge presents a key difference: datacenter clouds (both in terms of their infrastructure and the applications run by them) are owned and managed by a single organization, whereas edge clouds involve a complex ecosystem of operators, vendors, and application providers, all striving to provide a quality end-to-end solution to the user. This implies that, while the traditional cloud has been implemented for the most part by using vertically optimized and closed architectures, the edge will necessarily need to rely on a complete ecosystem of carefully designed open standards to enable horizontal interoperability across all the involved parties.¶

As an example, consider a user of an XR application who arrives at his/her home by car. The application runs by leveraging compute capabilities from both the car and the public 5G edge cloud. As the user parks the car, 5G coverage may diminish (due to building interference) making the home local Wi-Fi connectivity a better choice. Further, instead of relying on computational resources from the car and the 5G edge cloud, latency can be reduced by leveraging computing devices (PCs, laptops, tablets) available from the home edge cloud. The application's decision to switch from one domain to another, however, demands knowledge about the compute and communication resources available both in the 5G and the Wi-Fi domains, therefore requiring interoperability across multiple industry standards (for instance, IETF and 3GPP on the public side, and IETF and LF Edge [LF-EDGE] on the private home side).¶

4.3. Optimized Placement of Microservice Components

Current applications are transitioning from a monolithic service architecture towards the composition of microservice components, following cloud-native trends. The set of microservices can have associated Service Level Objectives (SLOs) that impose constraints not only in terms of the required computational resources dependent on the compute facilities available, but also in terms of performance indicators such as latency, bandwidth, etc, which impose restrictions in the networking capabilities connecting the computing facilities. Even more complex constraints, such as affinity among certain microservices components could require complex calculations for selecting the most appropriate compute nodes taken into consideration both network and compute information.¶

5.1. Producers of Compute-Related Information

The information relative to compute (e.g., processing capabilities, memory, storage capacity, etc.) can be structured in two ways. On one hand, the information corresponding to the raw compute resources; on the other hand, the information of resources allocated or utilized by a specific application or service function.¶

The former is typically provided by the management systems enabling the virtualization of the physical resources for a later assignment to the processes running on top. Cloud Managers or Virtual Infrastructure Managers are usually the entities that manage these resources. These management systems offer APIs to access the available resources in the computing facility. Thus, it can be expected that these APIs can also be used for consuming such information. Once the raw resources are retrieved from the various compute facilities, it is possible to generate topological network views including such resources, as proposed in [I-D.llc-teas-dc-aware-topo-model].¶

Regarding the resources allocated or utilized by a specific application or service function, two situations apply: (1) The total allocation of resources, and (2) the allocation per service or application. In the first case, the information can be supplied by the virtualization management systems described before. For the specific per-service allocation, it can be expected that the specific management systems of the service or application are capable of providing the resources being used at run time, typically as part of the allocated ones. In this last scenario, it is also reasonable to expect the availability of APIs offering this information, even though they can be specific to the service or application.¶

5.2. Consumers of Compute-Related Information

The consumption of compute-related information is relative to the different phases of the service lifecycle (Figure 1). This means that this information can be consumed in different points of time and for different purposes.¶

The expected consumers can be both external or internal to the network. As external consumers, it is possible to consider external application management systems requiring resource availability information for service function placement decision, workload migration in the case of consuming raw resources, or requiring information on the usage of resources for service assurance or service scaling, among others.¶

As internal consumers, it is possible to consider network management entities requiring information on the level of resource utilization for traffic steering (e.g., as done by the Path Selector in [I-D.ldbc-cats-framework]), load balance, or analytics, among others.¶

6.1. Considerations about Metrics

The metrics considered in this document are meant to support decisions for selection and deployment of services and applications. Further iterations of this document may consider additional lifecycle operations such as assurance and relevant metrics.¶

The abovementioned operation may also involve network metrics that are specified in a number of IETF documents such as RFC 9439 [I-D.ietf-alto-performance-metrics], which itself leverages on RFC 7679. The work on compute metrics at the IETF, on the other hand, is in its first stages and merely relates to low-level infrastructure metrics such as in [RFC7666]. However:¶

• Decisions for service deployment and selection may further involve decisions that require an aggregated view, for instance, at the service level.¶

• Deciding entities may only have partial access to the compute information and actually do not need to have all the details.¶

Compute metrics and their acquisition and management have been addressed by standardization bodies outside the IETF such as NIST and DMTF, with the goal to guarantee reliable assessment and comparison of cloud services. A number of public tools and methods to test compute facility performances are made available by cloud service providers or service management businesses (e.g., see [UPCLOUD] and [IR]). However, for the proposed performance metrics, their definition and acquisition method may differ from one provider to the other, making it thus challenging to compare performances across different providers. The latter aspect is particularly problematic for applications running at the edge where a complex ecosystem of operators, vendors, and application providers is involved and calls for a common standardized definition.¶

6.2. Decision Dimensions for Metrics Selection

Once defined, the compute metrics are to be selected and exposed to management entities acting at different levels, such as a centralized controller or a router, taking different actions such as service placement, service selection, and assurance, with decision scopes ranging from local compute facilities to end-to-end services.¶

Upon exploring existing work, this draft proposes to consider a number of "decision dimensions" reflecting the abovementioned aspects in order to help identifying the suitable compute metrics needed to take a service operation decision. This list is initial and is to be updated upon further discussion.¶

Dimensions helping to identify needed compute metrics:¶

The "value" of a dimension has an impact on the characteristic of the metric to consider. In particular:¶

• The target operation: determines the specific use case for the metric, such as monitoring, benchmarking, service placement, or selection, guiding the selection of relevant metrics.¶

• The driving KPI(s): leads to selecting metrics that are relevant from a performance standpoint.¶

• The decision scope: leads to selecting metrics at a relevant granularity or aggregation level.¶

• The receiving entity: impacts the dynamicity of the received metric values. While a router likely receives static information to moderate overhead, a centralized control function may receive more dynamic information that it may additionally process on its own.¶

• The deciding entity: computes the decisions to take upon metric values and needs information that is synchronized at an appropriate frequency.¶

Metric values undergo various lifecycle actions, primarily acquisition, processing, and exposure. These actions can be executed through different methodologies. Documenting these methodologies enhances the reliability and informed utilization of the metrics. Additionally, detailing the specific methods used for each approach further increases their reliability. The table below provides some examples:¶

6.3. Abstraction Level and Information Access

One important aspect to consider is that receiving entities that need to consume metrics to take selection or placement decisions do not always have access to computing information. In particular, several scenarios may need to be considered, among which:¶

• The consumer is an ISP that does not own the compute infrastructure or has no access to full information. In this case, the compute metrics will likely be estimated.¶

• The consumer is an application that has no direct access to full information while the ISP has access to both network and compute information. However the ISP is willing to provide guidance to the application with abstract information.¶

• The consumer has access to full network and compute information and wants to use it for fine-grained decision making, e.g., at the node/cluster level.¶

• The consumer has access to full information but essentially needs guidance with abstracted information.¶

• The consumer has access to information that is abstracted or detailed depending on the metrics.¶

These scenarios further drive the selection of metrics upon the above mentioned dimensions.¶

6.4. Distribution and Exposure Mechanisms

6.5. Examples of Resources

7.1. Understanding the Kubernetes Metrics API and its Exposure Mechanism

Figure 2 shows the Kubernetes Metric API architecture. It consists of the following components:¶

Pod. A collection of one or more containers.¶

Cluster. A collection of one or more nodes.¶

HPA, VPA and 'kubectl stop'. Three different applications that serve as examples of consumers of the Metrics API. The HorizontalPodAutoscaler (HPA) and VerticalPodAutoscaler (VPA) use data from the metrics API to adjust workload replicas and resources to meet customer demand. 'kubectl stop' can be used to show all the metrics.¶

cAdvisor. Daemon for collecting metrics (CPU, memory, GPU, etc.) from all the containers in a pod. It is responsible for aggregating and exposing these metrics to kubelet.¶

Kubelet. Node agent responsible for managing container resources. It includes the ability to collect the metrics from the cAdvisor and making them accessible using the /metrics/resource and /stats kubelet API endpoints.¶

Metrics server. Cluster agent responsible for collecting and aggregating resource metrics from each kubelet.¶

API Server. General server providing API access to kubernetes services. One of them corresponds to the Metrics API service. HPA, VPA, and 'kubectl top' query the API server to retrieve the metrics.¶

            +---------------------------------------------------------------------------------+
            |                                                                                 |
            |  Cluster                      +-----------------------------------------------+ |
            |                               |                                               | |
            |                               |  Node                           +-----------+ | |
            |                               |                                 | Container | | |
            |                               |                               +-+           | | |
            |                               |                               | |  runtime  | | |
            |                               |                 +----------+  | +-----------+ | |
+-------+   |                               |                 |          |  |               | |
|  HPA  <-+ |                               |               +-+ cAdvisor |<-+               | |
+-------+ | |                               |               | |          |  | +-----------+ | |
          | | +----------+    +-----------+ | +----------+  | +----------+  | | Container | | |
+-------+ | | |  API     |    |  Metrics  | | |          |  |               +-+           | | |
|  VPA  <-+-+-+          <--+-+           <-+-+ Kubelet  <--+                 |  runtime  | | |
+-------+ | | | server   |  | |   server  | | |          |  |                 +-----------+ | |
          | | +----------+  | +-----------+ | +----------+  |                               | |
+-------+ | |               |               |               |                               | |
|kubectl| | |               |               |               | +----------+                  | |
| top   <-+ |               | +-----------+ |               | |  Other   |                  | |
+-------+   |               | |  Other    | |               +-+   pod    |                  | |
            |               +-+           | |                 |   data   |                  | |
            |                 |  data     | |                 +----------+                  | |
            |                 +-----------+ |                                               | |
            |                               +-----------------------------------------------+ |
            |                                                                                 |
            +---------------------------------------------------------------------------------+

7.2. Example of How to Map the Kubernetes Metrics API with the IETF CATS METRICS Distribution

In this section, we describe a mapping between the Kubernetes Metrics API and the IETF CATS metric dissemination architecture, illustrating and example of how a de facto standard widely used in production systems can be adapted to support the CATS metrics framework.¶

To describe the mapping, we take the centralized model of the CATS metrics dissemination framework introduced in [I-D.ldbc-cats-framework], which we include in Figure 3 for ease of reading. (Similar mappings can be created with the distributed and hybrid models also introduced in this Figure 3)¶

            :       +------+
            :<------| C-PS |<----------------------------------+
            :       +------+ <------+              +--------+  |
            :          ^            |           +--|CS-ID 1 |  |
            :          |            |           |  |CIS-ID 1|  |
            :          |   +----------------+   |  +--------+  |
            :          |   |    C-SMA       |---|Service Site 2|
            :          |   +----------------+   |  +--------+  |
            :          |   |CATS-Forwarder 2|   +--|CS-ID 1 |  |
            :          |   +----------------+      |CIS-ID 2|  |
+--------+  :          |             |             +--------+  |
| Client |  :  Network |   +----------------------+            |
+--------+  :  metrics |   | +-------+            |            |
     |      :          +-----| C-NMA |            |      +-----+
     |      :          |   | +-------+            |      |C-SMA|<-+
+----------------+ <---+   |                      |      +-----+  |
|CATS-Forwarder 1|---------|                      |          ^    |
+----------------+         |       Underlay       |          |    |
            :              |     Infrastructure   |     +--------+|
            :              |                      |     |CS-ID 1 ||
            :              +----------------------+  +--|CIS-ID 3||
            :                        |               |  +--------+|
            :          +----------------+------------+            |
            :          |CATS-Forwarder 3|         Service Site 3  |
            :          +----------------+                         |
            :                        |       :      +-------+     |
            :                        +-------:------|CS-ID 2|-----+
            :                                :      +-------+
            :<-------------------------------:

The following table provides the mapping:¶

Note that while in Kubernetes there are multiple levels of abstraction to reach the Metrics API (cAdvisor -> kubelet -> metrics server -> API server), they can all be co-located in the cAdvisor, which can then be mapped to the C-SMA module in CATS.¶

7.3. Available Metrics from the Kubernetes Metrics API

The Kubernetes Metrics API implementation can be found in staging/src/k8s.io/kubelet/pkg/apis/stats/v1alpha1/types.go as part of the Kubernetes repository (https://github.com/kubernetes/kubernetes):¶

In this section we provide a summary of the metrics offered by the API:¶

For more details, refer to https://github.com/kubernetes/kubernetes under the path staging/src/k8s.io/kubelet/pkg/apis/stats/v1alpha1/types.go.¶