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github.com/chenjiandongx/sniffer @v0.6.3

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repository ↗ · DeepWiki ↗ · release v0.6.3 ↗ · + Follow
158 symbols 324 edges 12 files 15 documented · 9% updated 10mo agov0.6.3 · 2025-08-23★ 7863 open issues
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README

sniffer

GoDoc Go Report Card License

A modern alternative network traffic sniffer inspired by bandwhich(Rust) and nethogs(C++).

https://user-images.githubusercontent.com/19553554/147360587-a3cfee18-7eb6-464b-9173-9afe6ee86cdf.mov

Introduction

中文介绍

sniffer is designed for network troubleshooting. It can be started at any time to analyze the processes or connections causing increases in network traffic without loading any kernel modules. By the way, the TUI of it is responsive that can fit with terminals of all sizes automatically.

sniffer manipulates gopacket to sniff the interfaces and record packets' info. gopacket wraps the Golang port of libpacp library, and provides some additional features. One of the projects that inspired the sniffer is bandwhich, which has a sophisticated interface and multiple ways to display data, but it does not support BPF filters. Another one is nethlogs, which supports BPF filters, but can only view data by process, without connections or remote address perspective. sniffer combines the advantages of those two projects also adhering a new Plot mode.

Connections and Process Matching

On Linux, sniffer refers to the ways in which the ss tool used, obtaining the connections of the ESTABLISHED state by netlink socket. Since that approach is more efficient than reading the /proc/net/* files directly. But both need to aggregate and calculate the network traffic of the process by matching the inode information under /proc/${pid}/fd.

On macOS, the lsof command is invoked, which relies on capturing the command output for analyzing process connections information. And sniffer manipulates the API provided by gopsutil directly on Windows.

Installation

sniffer relies on the libpcap library to capture user-level packets hence you need to have it installed first.

Linux / Windows

Debian/Ubuntu

$ sudo apt-get install libpcap-dev

CentOS/Fedora

$ sudo yum install libpcap libpcap-devel

Windows

Windows need to have npcap installed for capturing packets.

After that, install sniffer by go get command.

$ go get -u github.com/chenjiandongx/sniffer

MacOS

$ brew install sniffer

Usages

❯ sniffer -h
# A modern alternative network traffic sniffer.

Usage:
  sniffer [flags]

Examples:
  # bytes mode in MB unit
  $ sniffer -u MB

  # only capture the TCP protocol packets with lo,eth prefixed devices
  $ sniffer -b tcp -d lo -d eth

Flags:
  -a, --all-devices                  listen all devices if present
  -b, --bpf string                   specify string pcap filter with the BPF syntax (default "tcp or udp")
  -d, --devices-prefix stringArray   prefixed devices to monitor (default [en,lo,eth,em,bond])
  -h, --help                         help for sniffer
  -i, --interval int                 interval for refresh rate in seconds (default 1)
  -l, --list                         list all devices name
  -m, --mode int                     view mode of sniffer (0: bytes 1: packets 2: plot)
  -n, --no-dns-resolve               disable the DNS resolution
  -u, --unit string                  unit of traffic stats, optional: B, Kb, KB, Mb, MB, Gb, GB (default "KB")
  -v, --version                      version for sniffer

Hotkeys

Keys Description
Space pause refreshing
Tab rearrange tables
s switch next view mode
q quit

Performance

iperf is a tool for active measurements of the maximum achievable bandwidth on IP networks. Next we use this tool to forge massive packets on the lo device.

$ iperf -s -p 5001
$ iperf -c localhost --parallel 40 -i 1 -t 2000

sniffer vs bandwhich vs nethogs

As you can see, CPU overheads bandwhich > sniffer > nethogs, memory overheads sniffer > nethogs > bandwhich.

    PID USER      PR  NI    VIRT    RES    SHR S  %CPU  %MEM     TIME+ COMMAND
 128405 root      20   0  210168   5184   3596 S  31.0   0.3   1:21.69 bandwhich
 128596 root      20   0 1449872  21912   8512 S  20.7   1.1   0:28.54 sniffer
 128415 root      20   0   18936   7464   6900 S   5.7   0.4   0:11.56 nethogs

See what stats they show, sniffer and bandwhich output are very approximate(~ 2.5GB/s). netlogs can only handles packets 1.122GB/s.

sniffer bandwhich nethogs
Upload 2.5GiBps 2.5GiBps 1.12GiBps

View Mode

Bytes Mode: display traffic stats in bytes by the Table widget.

Packets Mode: display traffic stats in packets by the Table widget.

License

MIT ©chenjiandongx

Extension points exported contracts — how you extend this code

SocketFetcher (Interface)
(no doc) [3 implementers]
pcap.go
Invoker (Interface)
(no doc) [2 implementers]
conn_darwin.go
Viewer (Interface)
(no doc) [2 implementers]
ui.go
Lookup (FuncType)
(no doc)
dns.go

Core symbols most depended-on inside this repo

humanizeNum
called by 16
ui.go
String
called by 14
ui.go
Put
called by 6
ui.go
exit
called by 5
sniffer.go
Get
called by 5
ui.go
Render
called by 5
ui.go
newQueue
called by 5
ui.go
Resize
called by 4
ui.go

Shape

Method 87
Struct 37
Function 22
TypeAlias 8
Interface 3
FuncType 1

Languages

Go100%

Modules by API surface

ui.go46 symbols
conn_linux.go24 symbols
stat.go19 symbols
pcap.go19 symbols
sniffer.go10 symbols
pcap_linux.go9 symbols
pcap_others.go8 symbols
conn_darwin.go7 symbols
dns.go6 symbols
conn_windows.go5 symbols
conn_darwin_test.go3 symbols
cli.go2 symbols

For agents

$ claude mcp add sniffer \
  -- python -m otcore.mcp_server <graph>

⬇ download graph artifact

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