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GoFlow2

Build Status Go Reference

This application is a NetFlow/IPFIX/sFlow collector in Go.

It gathers network information (IP, interfaces, routers) from different flow protocols, serializes it in a common format.

You will want to use GoFlow if:

  • You receive a decent amount of network samples and need horizontal scalability
  • Have protocol diversity and need a consistent format
  • Require raw samples and build aggregation and custom enrichment

This software is the entry point of a pipeline. The storage, transport, enrichment, graphing, alerting are not provided.

GoFlow2 System diagram

Origins

This work is a fork of a previous open-source GoFlow code built and used at Cloudflare. It lives in its own GitHub organization to be maintained more easily.

Among the differences with the original code: The serializer and transport options have been revamped to make this program more user-friendly and target new use-cases like logging providers. Minimal changes in the decoding libraries.

Modularity

In order to enable load-balancing and optimizations, the GoFlow2 library has a decoder which converts the payload of a flow packet into a structure.

The producer converts the samples into another format. Out of the box, this repository provides a protobuf producer (pb/flow.pb) and a raw producer. In the case of the protobuf producer, the records in a single flow packet are extracted and made in their own protobuf. Custom mapping allows to add new fields without rebuilding the proto.

The format directory offers various utilities to format a message. It calls specific functions to marshal as JSON or text for instance.

The transport provides different way of processing the message. Either sending it via Kafka or send it to a file (or stdout).

GoFlow2 is a wrapper of all the functions and chains them.

You can build your own collector using this base and replace parts:

  • Use different transport (e.g: RabbitMQ instead of Kafka)
  • Convert to another format (e.g: Cap'n Proto, Avro, instead of protobuf)
  • Decode different samples (e.g: not only IP networks, add MPLS)
  • Different metrics system (e.g: OpenTelemetry)

Protocol difference

The sampling protocols have distinct features:

sFlow is a stateless protocol which sends the full header of a packet with router information (interfaces, destination AS) while NetFlow/IPFIX rely on templates that contain fields (e.g: source IPv6).

The sampling rate in NetFlow/IPFIX is provided by Option Data Sets. This is why it can take a few minutes for the packets to be decoded until all the templates are received (Option Template and Data Template).

Both of these protocols bundle multiple samples (Data Set in NetFlow/IPFIX and Flow Sample in sFlow) in one packet.

The advantages of using an abstract network flow format, such as protobuf, is it enables summing over the protocols (e.g: per ASN or per port, rather than per (ASN, router) and (port, router)).

To read more about the protocols and how they are mapped inside, check out page

Features of GoFlow2

Collection:

  • NetFlow v5
  • IPFIX/NetFlow v9 (sampling rate provided by the Option Data Set)
  • sFlow v5

(adding NetFlow v1,7,8 is being evaluated)

Production:

  • Convert to protobuf or json
  • Prints to the console/file
  • Sends to Kafka and partition

Monitoring via Prometheus metrics

Get started

To read about agents that samples network traffic, check this page.

To set up the collector, download the latest release corresponding to your OS and run the following command (the binaries have a suffix with the version):

$ ./goflow2

By default, this command will launch an sFlow collector on port :6343 and a NetFlowV9/IPFIX collector on port :2055.

By default, the samples received will be printed in JSON format on the stdout.

{
    "type": "SFLOW_5",
    "time_received_ns": 1681583295157626000,
    "sequence_num": 2999,
    "sampling_rate": 100,
    "sampler_address": "192.168.0.1",
    "time_flow_start_ns": 1681583295157626000,
    "time_flow_end_ns": 1681583295157626000,
    "bytes": 1500,
    "packets": 1,
    "src_addr": "fd01::1",
    "dst_addr": "fd01::2",
    "etype": "IPv6",
    "proto": "TCP",
    "src_port": 443,
    "dst_port": 50001
}

If you are using a log integration (e.g: Loki with Promtail, Splunk, Fluentd, Google Cloud Logs, etc.), just send the output into a file.

$ ./goflow2 -transport.file /var/logs/goflow2.log

To enable Kafka and send protobuf, use the following arguments:

$ ./goflow2 -transport=kafka \
  -transport.kafka.brokers=localhost:9092 \
  -transport.kafka.topic=flows \
  -format=bin

By default, the distribution will be randomized. In order to partition the field, you need to configure the key in the formatter.

By default, compression is disabled when sending data to Kafka. To change the kafka compression type of the producer side configure the following option:

-transport.kafka.compression.type=gzip

The list of codecs is available in the Sarama documentation.

By default, the collector will listen for IPFIX/NetFlow V9 on port 2055 and sFlow on port 6343. To change the sockets binding, you can set the -listen argument and a URI for each protocol (netflow, sflow and nfl as scheme) separated by a comma. For instance, to create 4 parallel sockets of sFlow and one of NetFlow V5, you can use:

$ ./goflow2 -listen 'sflow://:6343?count=4,nfl://:2055'

More information about workers and resource usage is avaialble on the Performance page.

Docker

You can also run directly with a container:

$ sudo docker run -p 6343:6343/udp -p 2055:2055/udp -ti netsampler/goflow2:latest

Mapping extra fields

In the case of exotic template fields or extra payload not supported by GoFlow2 of out the box, it is possible to pass a mapping file using -mapping mapping.yaml. A sample file is available in the cmd/goflow2 directory.

For instance, certain devices producing IPFIX use ingressPhysicalInterface (id: 252) and do not use ingressInterface (id: 10). Using the following you can have the interface mapped in the InIf protobuf field without changing the code.

ipfix:
  mapping:
    - field: 252
      destination: in_if
    - field: 253
      destination: out_if

Output format considerations

The JSON format is advised only when consuming a small amount of data directly. For bigger workloads, the protobuf output format provides a binary representation and is preferred. It can also be extended with enrichment as long as the user keep the same IDs.

If you want to develop applications, build pb/flow.proto into the language you want: When adding custom fields, picking a field ID ≥ 1000 is suggested.

Check the docs for more information about compiling protobuf.

Flow Pipeline

A basic enrichment tool is available in the cmd/enricher directory. You need to load the Maxmind GeoIP ASN and Country databases using -db.asn and -db.country.

Running a flow enrichment system is as simple as a pipe. Once you plug the stdin of the enricher to the stdout of GoFlow in protobuf, the source and destination IP addresses will automatically be mapped with a database for Autonomous System Number and Country. Similar output options as GoFlow are provided.

$ ./goflow2 -transport.file.sep= -format=bin | \
  ./enricher -db.asn path-to/GeoLite2-ASN.mmdb -db.country path-to/GeoLite2-Country.mmdb

For a more scalable production setting, Kafka and protobuf are recommended. Stream operations (aggregation and filtering) can be done with stream-processor tools. For instance Flink, or the more recent Kafka Streams and kSQLdb. Direct storage can be done with data-warehouses like Clickhouse.

Each protobuf message is prefixed by its varint length.

This repository contains examples of pipelines with docker-compose. The available pipelines are:

Security notes and assumptions

By default, the buffer for UDP is 9000 bytes. Protections were added to avoid DOS on sFlow since the various length fields are 32 bits. There are assumptions on how many records and list items a sample can have (eg: AS-Path).

User stories

Are you using GoFlow2 in production at scale? Add yourself here!

Contributions

This project welcomes pull-requests, whether it's documentation, instrumentation (e.g: docker-compose, metrics), internals (protocol libraries), integration (new CLI feature) or else! Just make sure to check for the use-cases via an issue.

This software would not exist without the testing and commits from its users and contributors.

License

Licensed under the BSD-3 License.