Ultra Ethernet Transport

The Ultra Ethernet Consortium has a mission to Deliver an Ethernet based open, interoperable, high performance, full-communications stack architecture to meet the growing network demands of AI & HPC at scale. The recently released UE-Specification-1.0.1 includes an Ultra Ethernet Transport (UET) protocol with similar functionality to RDMA over Converged Ethernet (RoCEv2).

The sFlow instrumentation embedded as a standard feature of data center switch hardware from all leading vendors (Arista, Cisco, Dell, Juniper, NVIDIA, etc.) provides a cost effective solution for gaining visibility into UET traffic in large production AI / ML fabrics. 

docker run -p 8008:8008 -p 6343:6343/udp sflow/prometheus

The easiest way to get started is to use the pre-built sflow/prometheus Docker image to analyze the sFlow telemetry. The chart at the top of this page shows an up to the second view of UET operations using the included Flow Browser application, see Defining Flows for a list of available UET attributes. Getting Started describes how to set up the sFlow monitoring system.

Flow metrics with Prometheus and Grafana describes how collect custom network traffic flow metrics using the Prometheus time series database and include the metrics in Grafana dashboards. Use the Flow Browser to explore UET flow metrics and then configure a Prometheus scrape task to collect useful operational metrics.

Vector Packet Processor (VPP) dropped packet notifications

Vector Packet Processor (VPP) release 25.10 extends the sFlow implementation to include support for dropped packet notifications, providing detailed, low overhead, visibility into traffic flowing through a VPP router, see Vector Packet Processor (VPP) for performance information.

sflow sampling-rate 10000
sflow polling-interval 20
sflow header-bytes 128
sflow direction both
sflow drop-monitoring enable
sflow enable GigabitEthernet0/8/0
sflow enable GigabitEthernet0/9/0
sflow enable GigabitEthernet0/a/0

The above VPP configuration commands enable sFlow monitoring of the VPP dataplane, randomly sampling packets, periodically polling counters, and capturing dropped packets and reason codes. The measurements are send via Linux netlink messages to an instance of the open source Host sFlow agent (hsflowd) which combines the measurements and streams standard sFlow telemetry to a remote collector.

sflow {
  collector { ip=192.0.2.1 udpport=6343 }
  psample { group=1 egress=on }
  dropmon { start=on limit=50 }
  vpp { }
}

The /etc/hsflowd.conf file above enables the modules needed to receive netlink messages from VPP and send the resulting sFlow telemetry to a collector at 192.0.2.1. See vpp-sflow for detailed instructions.

docker run -p 6343:6343/udp sflow/sflowtool

Run sflowtool on the sFlow collector host to verify verify that the data is being received and to see the information available in the sFlow telemetry stream. The pre-built sflow/sflowtool Docker image is the fastest way to run sflowtool.

Docker also makes it easy to try out other sFlow analytics tools, for example, Deploy real-time network dashboards using Docker compose, describes how to quickly set up measurement stack consisting of the sFlow-RT real-time analytics engine, Prometheus time series database, and Grafana dashboard builder.

The sFlow VPP module delivers the same industry standard network performance monitoring available in switches and routers from leading vendors, including Arista, Cisco, Dell, Juniper, NVIDIA, VyOS, etc. to provide comprehensive, network-wide, visibility.

AI / ML network performance metrics at scale

The charts above show information from a GPU cluster running an AI / ML training workload. The 244 nodes in the cluster are connected by 100G links to a single large switch. Industry standard sFlow telemetry from the switch is shown in the two trend charts generated by the sFlow-RT real-time analytics engine. The charts are updated every 100mS.

• Per Link Telemetry shows RoCEv2 traffic on 5 randomly selected links from the cluster. Each trend is computed based on sFlow random packet samples collected on the link. The packet header in each sample is decoded and the metric is computed for packets identified as RoCEv2.
• Combined Fabric-Wide Telemetry combines the signals from all the links to create a fabric wide metric. The signals are highly correlated since the AI training compute / exchange cycle is synchronized across all compute nodes in the cluster. Constructive interference from combining data from all the links removes the noise in each individual signal and clearly shows the traffic pattern for the cluster.

This is a relatively small cluster. For larger clusters, the effect is even more pronounced, resulting in extremely sharp cluster-wide metrics. The sFlow instrumentation embedded as a standard feature of data center switch hardware from all leading vendors (Arista, Cisco, Dell, Juniper, NVIDIA, etc.) provides a cost effective solution for even the largest AI / ML fabrics.

The Grafana AI Metrics dashboard shown above tracks performance metrics for AI/ML RoCEv2 network traffic, for example, large scale CUDA compute tasks using NVIDIA Collective Communication Library (NCCL) operations for inter-GPU communications: AllReduce, Broadcast, Reduce, AllGather, and ReduceScatter.

The metrics include:

• Total Traffic Total traffic entering fabric
• Operations Total RoCEv2 operations broken out by type
• Core Link Traffic Histogram of load on fabric links
• Edge Link Traffic Histogram of load on access ports
• RDMA Operations Total RDMA operations
• RDMA Bytes Average RDMA operation size
• Credits Average number of credits in RoCEv2 acknowledgements
• Period Detected period of compute / exchange activity on fabric (in this case just over 0.5 seconds)
• Congestion Total ECN / CNP congestion messages
• Errors Total ingress / egress errors
• Discards Total ingress / egress discards
• Drop Reasons Packet drop reasons

Enable sFlow in your AI / ML networks for detailed visibility into network performance. Instructions are provided in the articles: AI Metrics, AI Metrics with Prometheus and Grafana and AI Metrics with Grafana Cloud.

Packet trimming

The latest version of the AI Metrics dashboard uses industry standard sFlow telemetry from network switches to monitor the number of trimmed packets to use as a congestion metric.

Ultra Ethernet Specification Update describes how the Ultra Ethernet Transport (UET) Protocol has the ability to leverage optional “packet trimming” in network switches, which allows packets to be truncated rather than dropped in the fabric during congestion events. As packet spraying causes reordering, it becomes more complicated to detect loss. Packet trimming gives the receiver and the sender an early explicit indication of congestion, allowing immediate loss recovery in spite of reordering, and is a critical feature in the low-RTT environments where UET is designed to operate.

cumulus@switch:~$ nv set system forwarding packet-trim profile packet-trim-default
cumulus@switch:~$ nv config apply

NVIDIA Cumulus Linux release 5.14 for NVIDA Spectrum Ethernet Switches includes support for Packet Trimming. The above command enables packet trimming, sets the DSCP remark value to 11, sets the truncation size to 256 bytes, sets the switch priority to 4, and sets the eligibility to all ports on the switch with traffic class 1, 2, and 3. NVIDA BlueField host adapters respond to trimmed packets to ensure fast congestion recovery.

Instructions for deploying the Grafana AI Metrics dashboard are provided in the articles: AI Metrics, AI Metrics with Prometheus and Grafana and AI Metrics with Grafana Cloud.

Linux packet sampling using eBPF

Linux 6.11+ kernels provide TCX attachment points for eBPF programs to efficiently examine packets as they ingress and egress the host. The latest version of the open source Host sFlow agent includes support for TCX packet sampling to stream industry standard sFlow telemetry to a central collector for network wide visibility, e.g. Deploy real-time network dashboards using Docker compose describes how to quickly set up a Prometheus database and use Grafana to build network dashboards.

static __always_inline void sample_packet(struct __sk_buff *skb, __u8 direction) {
    __u32 key = skb->ifindex;
    __u32 *rate = bpf_map_lookup_elem(&sampling, &key);
    if (!rate || (*rate > 0 && bpf_get_prandom_u32() % *rate != 0))
        return;

    struct packet_event_t pkt = {};
    pkt.timestamp = bpf_ktime_get_ns();
    pkt.ifindex = skb->ifindex;
    pkt.sampling_rate = *rate;
    pkt.ingress_ifindex = skb->ingress_ifindex;
    pkt.routed_ifindex = direction ? 0 : get_route(skb);
    pkt.pkt_len = skb->len;
    pkt.direction = direction;

    __u32 hdr_len = skb->len < MAX_PKT_HDR_LEN ? skb->len : MAX_PKT_HDR_LEN;
    if (hdr_len > 0 && bpf_skb_load_bytes(skb, 0, pkt.hdr, hdr_len) < 0)
        return;
    bpf_perf_event_output(skb, &events, BPF_F_CURRENT_CPU, &pkt, sizeof(pkt));
}

SEC("tcx/ingress")
int tcx_ingress(struct __sk_buff *skb) {
    sample_packet(skb, 0);

    return TCX_NEXT;
}

SEC("tcx/egress")
int tcx_egress(struct __sk_buff *skb) {
    sample_packet(skb, 1);

    return TCX_NEXT;
}

The sample.bpf.c file is compiled into eBPF code that the Host sFlow mod_epcap.c module uses to tap packets on selected interfaces. The highlighted code uses the bpf_get_random_u32() function to randomly select packets using the configured sampling rate for the interface. Once a packet is selected to be sampled, the packet header and selected metadata is captured and sent to the Host sFlow agent as a performance event via the bpf_perf_event_output() call. The ability to perform the sampling action in the kernel dramatically reduces the overhead associated with network traffic monitoring, since only the small fraction of sampled packets need to be transferred to the user space Host sFlow agent.

static __always_inline __u32 get_route(struct __sk_buff *skb) {
    __u32 key = 0;
    __u32 *routing_enabled = bpf_map_lookup_elem(&routing, &key);
    if(!routing_enabled || !*routing_enabled)
	return 0;

    if(skb->pkt_type != PACKET_HOST)
	return 0;

    void *data = (void *)(long)skb->data;
    void *data_end = (void *)(long)skb->data_end;
    struct ethhdr *eth = data;
    if ((void *)(eth + 1) > data_end)
        return 0;
    __u32 proto = bpf_ntohs(eth->h_proto);
    if(proto == ETH_P_IP) {
        struct iphdr *ip = data + sizeof(*eth);
        if ((void *)(ip + 1) > data_end)
            return 0;
        struct bpf_fib_lookup fib = {0};
        fib.family      = AF_INET;
        fib.ipv4_src    = ip->saddr;
        fib.ipv4_dst    = ip->daddr;
        fib.tos         = ip->tos;
	fib.l4_protocol = ip->protocol;
	fib.sport       = 0;
	fib.dport       = 0;
	fib.tot_len     = bpf_ntohs(ip->tot_len);
        fib.ifindex     = skb->ifindex;
        long rc = bpf_fib_lookup(skb, &fib, sizeof(fib), 0);
        if(rc != BPF_FIB_LKUP_RET_SUCCESS)
	   return 0;
        return fib.ifindex;
    } else if(proto == ETH_P_IPV6) {
	struct ipv6hdr *ipv6 = data + sizeof(*eth);
        if ((void *)(ipv6 + 1) > data_end)
	    return 0;
        struct bpf_fib_lookup fib = {0};
        fib.family      = AF_INET6;
	__builtin_memcpy(fib.ipv6_src, &ipv6->saddr, sizeof(ipv6->saddr));
        __builtin_memcpy(fib.ipv6_dst, &ipv6->daddr, sizeof(ipv6->daddr));
	fib.flowinfo    = *(__be32 *) ipv6 & bpf_htonl(0x0FFFFFFF);
	fib.l4_protocol = ipv6->nexthdr;
	fib.sport       = 0;
	fib.dport       = 0;
	fib.tot_len     = bpf_ntohs(ipv6->payload_len);
        fib.ifindex     = skb->ifindex;
        long rc = bpf_fib_lookup(skb, &fib, sizeof(fib), 0);
        if(rc != BPF_FIB_LKUP_RET_SUCCESS)
           return 0;
        return fib.ifindex;	
    }
    return 0;
}

If the Linux host has been configured as a router, then the bpf_fib_lookup() is used to to determine the forwarding decision (egress port) for sampled ingress packets.

Note: The mod_pcap.c module works on older Linux kernels and uses traditional BPF to perform random packet sampling. The main advantage of the mod_epcap module is its ability add additional metadata to each sampled packet.

Tracing network packets with eBPF and pwru

pwru (packet, where are you?) is an open source tool from Cilium that used eBPF instrumentation in recent Linux kernels to trace network packets through the kernel.

In this article we will use Multipass to create a virtual machine to experiment with pwru. Multipass is a command line tool for running Ubuntu virtual machines on Mac or Windows. Multipass uses the native virtualization capabilities of the host operating system to simplify the creation of virtual machines.

multipass launch --name=ebpf noble
multipass exec ebpf -- sudo apt update
multipass exec ebpf -- sudo apt -y install git clang llvm make libbpf-dev flex bison golang
multipass exec ebpf -- git clone https://github.com/cilium/pwru.git
multipass exec ebpf --working-directory pwru -- make
multipass exec ebpf -- sudo ./pwru/pwru -h

Run the commands above to create the virtual machine and build pwru from sources.

multipass exec ebpf -- sudo ./pwru/pwru port https

Run pwru to trace https traffic on the virtual machine.

multipass exec ebpf -- curl https://sflow-rt.com

In a second window, run the above command to generate an https request from the virtual machine.

SKB                CPU PROCESS          NETNS      MARK/x        IFACE       PROTO  MTU   LEN   TUPLE FUNC
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0               0         0x0000 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) ip_local_out
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0               0         0x0000 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) __ip_local_out
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0               0         0x0800 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) ip_output
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) nf_hook_slow
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) apparmor_ip_postroute
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) ip_finish_output
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) __ip_finish_output
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) ip_finish_output2
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) neigh_resolve_output
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) eth_header
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  60    192.168.66.3:47460->54.190.130.38:443(tcp) skb_push
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) __dev_queue_xmit
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) qdisc_pkt_len_init
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) netdev_core_pick_tx
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) sch_direct_xmit
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) validate_xmit_skb_list
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) validate_xmit_skb
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) netif_skb_features
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) passthru_features_check
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) skb_network_protocol
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) skb_csum_hwoffload_help
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) skb_checksum_help
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) skb_ensure_writable
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) validate_xmit_xfrm
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) dev_hard_start_xmit
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) start_xmit
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) skb_clone_tx_timestamp
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  74    192.168.66.3:47460->54.190.130.38:443(tcp) xmit_skb
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  86    192.168.66.3:47460->54.190.130.38:443(tcp) skb_to_sgvec
0xffff9fc40335a0e8 0   ~r/bin/curl:8966 4026531840 0             ens3:2      0x0800 1500  86    192.168.66.3:47460->54.190.130.38:443(tcp) __skb_to_sgvec

The pwru output provides a detailed trace of each packet through the Linux stack, identifying each application, namespace, interface and kernel module traversed by the packet. Type Ctrl+C to stop the trace.

multipass exec ebpf -- sudo ufw default allow
multipass exec ebpf -- sudo ufw deny out to any port https
multipass exec ebpf -- sudo ufw enable

Now create a firewall rule to block outgoing https traffic and repeat the test

SKB                CPU PROCESS          NETNS      MARK/x        IFACE       PROTO  MTU   LEN   TUPLE FUNC
0xffff970bc5f568e8 0   ~r/bin/curl:7138 4026531840 0               0         0x0000 1500  60    192.168.67.5:38932->54.190.130.38:443(tcp) ip_local_out
0xffff970bc5f568e8 0   ~r/bin/curl:7138 4026531840 0               0         0x0000 1500  60    192.168.67.5:38932->54.190.130.38:443(tcp) __ip_local_out
0xffff970bc5f568e8 0   ~r/bin/curl:7138 4026531840 0               0         0x0800 1500  60    192.168.67.5:38932->54.190.130.38:443(tcp) nf_hook_slow
0xffff970bc5f568e8 0   ~r/bin/curl:7138 4026531840 0               0         0x0800 1500  60    192.168.67.5:38932->54.190.130.38:443(tcp) kfree_skb_reason(SKB_DROP_REASON_NETFILTER_DROP)
0xffff970bc5f568e8 0   ~r/bin/curl:7138 4026531840 0               0         0x0800 1500  60    192.168.67.5:38932->54.190.130.38:443(tcp) skb_release_head_state
0xffff970bc5f568e8 0   ~r/bin/curl:7138 4026531840 0               0         0x0800 0     60    192.168.67.5:38932->54.190.130.38:443(tcp) tcp_wfree
0xffff970bc5f568e8 0   ~r/bin/curl:7138 4026531840 0               0         0x0800 0     60    192.168.67.5:38932->54.190.130.38:443(tcp) skb_release_data
0xffff970bc5f568e8 0   ~r/bin/curl:7138 4026531840 0               0         0x0800 0     60    192.168.67.5:38932->54.190.130.38:443(tcp) kfree_skbmem

This time, the curl command hangs and the pwru trace shows that packets are being dropped in the Linux firewall.

multipass exec ebpf -- sudo ufw disable

Disable the firewall.

There are additional multipass commands available to manage the virtual machine.

multipass shell ebpf

Connect to the virtual machine and access a command shell.

multipass stop ebpf

Stop the virtual machine.

multipass start ebpf

Start the virtual machine.

multipass delete ebpf
multipass purge

Delete the virtual machine.

AI Metrics with InfluxDB Cloud

The InfluxDB AI Metrics dashboard shown above tracks performance metrics for AI/ML RoCEv2 network traffic, for example, large scale CUDA compute tasks using NVIDIA Collective Communication Library (NCCL) operations for inter-GPU communications: AllReduce, Broadcast, Reduce, AllGather, and ReduceScatter.

The metrics include:

• Total Traffic Total traffic entering fabric
• Operations Total RoCEv2 operations broken out by type
• Core Link Traffic Histogram of load on fabric links
• Edge Link Traffic Histogram of load on access ports
• RDMA Operations Total RDMA operations
• RDMA Bytes Average RDMA operation size
• Credits Average number of credits in RoCEv2 acknowledgements
• Period Detected period of compute / exchange activity on fabric (in this case just over 0.5 seconds)
• Congestion Total ECN / CNP congestion messages
• Errors Total ingress / egress errors
• Discards Total ingress / egress discards
• Drop Reasons Packet drop reasons

This article shows how to integrate with InfluxDB Cloud instead of running the services locally.

Note: InfluxDB Cloud has a free service tier that can be used to test this example.

Save the following compose.yml file on a system running Docker.

configs:
  config.telegraf:
    content: |
      [agent]
        interval = '15s'
        round_interval = true
        omit_hostname = true
      [[outputs.influxdb_v2]]
        urls = ['https://<INFLUXDB_CLOUD_INSTANCE>.cloud2.influxdata.com']
        token = '<INFLUXDB_CLOUD_TOKEN>'
        organization = '<INFLUXDB_CLOUD_USER>'
        bucket = 'sflow'
      [[inputs.prometheus]]
        urls = ['http://sflow-rt:8008/app/ai-metrics/scripts/metrics.js/prometheus/txt']
        metric_version = 1

networks:

  monitoring:
    driver: bridge

services:

  sflow-rt:
    image: sflow/ai-metrics
    container_name: sflow-rt
    restart: unless-stopped
    ports:
      - '6343:6343/udp'
      - '8008:8008'
    networks:
      - monitoring

  telegraf:
    image: telegraf:alpine
    container_name: telegraf
    restart: unless-stopped
    configs:
      - source: config.telegraf
        target: /etc/telegraf/telegraf.conf
    depends_on:
      - sflow-rt
    networks:
      - monitoring

Use the Load Data menu to create an sflow bucket, create an API TOKEN to upload data, and find TELEGRAF INFLUXDB OUTPUT PLUGIN settings. Navigate to the Dashboards menu and create a new dashboard by importing ai_metrics.json

Edit the highlighted outputs.influxdb_v2 telegraf settings (INFLUXDB_CLOUD_INSTANCE, INFLUXDB_CLOUD_TOKEN and INFLUXDB_CLOUD_USER) to match those provided by InfluxDB Cloud.

docker compose up -d

Run the command above to start streaming metrics to InfluxDB Cloud.

Enable sFlow on all switches in the cluster (leaf and spine) using the recommeded settings. Enable sFlow dropped packet notifications to populate the drop reasons metric, see Dropped packet notifications with Arista Networks, NVIDIA Cumulus Linux 5.11 for AI / ML and Dropped packet notifications with Cisco 8000 Series Routers for examples.

Note: Tuning Performance describes how to optimize settings for very large clusters.

Industry standard sFlow telemetry is uniquely suited monitoring AI workloads. The sFlow agents leverage instrumentation built into switch ASICs to stream randomly sampled packet headers and metadata in real-time. Sampling provides a scaleable method of monitoring the large numbers of 400G/800G links found in AI fabrics. Export of packet headers allows the sFlow collector to decode the InfiniBand Base Transport headers to extract operations and RDMA metrics. The Dropped Packet extension uses Mirror-on-Drop (MoD) / What Just Happened (WJH) capabilities in the ASIC to include packet header, location, and reason for EVERY dropped packet in the fabric.

Talk to your switch vendor about their plans to support the Transit delay and queueing extension. This extension provides visibility into queue depth and switch transit delay using instrumentation built into the ASIC.

A network topology is required to generate the analytics, see Topology for a description of the JSON file and instructions for generating topologies from Graphvis DOT format, NVIDIA NetQ, Arista eAPI, and NetBox.

Use the Topology Status dashboard to verify that the topology is consistent with the sFlow telemetry and fully monitored. The Locate tab can be used to locate network addresses to access switch ports.

Note: If any gauges indicate an error, click on the gauge to get specific details.

Congratulations! The configuration is now complete and you should see charts above in AI Metric application Traffic tab. In addition, the AI Metrics dashboard at the top of this page should start to populate with data.

Getting Started provides an introductions to sFlow-RT, describes how to browse metrics and traffic flows using tools included in the Docker image, and links to information on creating applications using sFlow-RT APIs.