Cowrie author here! Yes this is the usual background noise on the internet! Cowrie (which I suspect is used here as well as the data generator) recently had a lot of updates, including now easy install from pip (pip install cowrie), and a much improved shell parser that’s much more capable of parsing attacker commands! https://github.com/cowrie/cowrie and get the full raw data in JSON or other formats to add geoip and ASN attribution! And of course malware samples.
Hi tusksm! It's honeypot season! Really cool project, I've been working on a honeypot project of my own right now called `honeyprompt` (https://github.com/alectrocute/honeyprompt) that utilizes LLMs to craft responses and supports multiple protocols. Having a public sink presentation layer like honeypotlive.cc was one of my next todos.
Opened the website to be greeted with only spam of huge walls of random text, seems people are abusing the fun out of it! Would love to actually have seen some interesting bot patterns from the authors comments.
You're right. HN traffic quickly turned the live feed from bot activity into a wall of human-generated test payloads.
I'm already working on truncating long values and grouping events by source. The next step will probably be rate limiting noisy sources and separating likely human test traffic from recurring automated behavior.
The recurring bot patterns are the part I ultimately want the interface to surface, rather than forcing visitors to inspect every raw event.
You know what extra data would be cool? If you hit `curl https://ip.guide/{src_ip}` and got back the ASN and country etc and added a leaderboard. In my own experiments in this area I've been gobsmacked by how much malicious traffic comes from Azure.
I have a similar experience with a tendency to Digital Ocean. Actually, I semi-automatically collect IPs that are banned by (mostly SSH) fail2ban and eBPF bans from dnsdist. These IPs are then merged into CIDRs, which are used as ipsets in a firewall ban chain. The IPs are collected on around ~20 Machines with public, static IPv4 and IPv6 addresses. Most of the Machines are in Canada and Europe.
However, I have statistics for the CIDRs based on their whois record that look like:
CIDRs used: 1255
Already cached: 1252
Skipped uncached targets: 0
IPs scanned total: 985300
Estimated throttled wait: 0.10 minutes
== Country codes ==
Metric: Top 10 of 90 unique country codes
Total: 1183 country codes total and 90 unique country codes in 1255 targets
US 287
CN 132
NL 88
VN 53
DE 51
HK 45
AU 38
ID 36
RU 33
CA 27
== Regions ==
Metric: Top 10 of 29 unique regions
Total: 334 regions total and 29 unique regions in 1255 targets
CO 48
FL 40
WA 37
QLD 32
GA 26
NY 25
CA 23
TX 17
QC 15
UT 14
== Origin ASNs ==
Metric: Top 10 of 382 unique origin ASNs
Total: 805 origin ASNs total and 382 unique origin ASNs in 1255 targets
Total: 703 org names total and 222 unique org names in 1255 targets
RIPE Network Coordination Centre 55
DigitalOcean, LLC 40
Asia Pacific Network Information Centre 32
Microsoft Corporation 31
Internap Holding LLC 25
HostPapa 23
Korea Telecom 20
Hetzner Online GmbH 17
China Mobile 16
ReliableSite.Net LLC 16
== Organizations ==
Metric: Top 10 of 236 unique organizations
Total: 691 organizations total and 236 unique organizations in 1255 targets
RIPE Network Coordination Centre (RIPE) 55
DigitalOcean, LLC (DO-13) 40
Asia Pacific Network Information Centre (APNIC) 32
Microsoft Corporation (MSFT) 31
Internap Holding LLC (IC-1425) 25
HostPapa (HOSTP-7) 23
ORG-HOA1-RIPE 17
ORG-CM1-AP 16
ReliableSite.Net LLC (RL-323) 15
FranTech Solutions (SYNDI-5) 13
== Domains ==
Metric: Top 10 of 534 unique domains
Total: 2581 domains total and 534 unique domains in 1255 targets
I deleted the (abuse) mail section. Because.
99% of the IPs are IPv4. In the IPset are mostly /32 but also a lot of ~/24 and rarely ~/16 segments. RIPE, ARIN and APNIC comes into play because some CIDR blocks are somewhat generously sized and block multiple network segments belonging to different organizations at the same time. E.g. this hides BR from the stats (because the ipset mostly bans every provider from BR).
For the sake of interest you could try to expose periodically rotated keyed hashes of IPs and credentials instead of the raw values. It would still let people correlate events within a limited time window
Do you allow them entry, present a fake prompt, and record what they do?
Some time ago I did a little experiment by running `nc -l -p 23` (telnet) which connects the next incoming telnet connection to your console. Type in a simulated prompt like Password: or # and it'll be buffered until the connection comes in. Then see what the scanner sends.
I maintain several web servers and kept seeing a constant stream of SSH login attempts. At some point I became curious: what do these bots actually try to do after they get in?
I set up a Cowrie SSH honeypot and built a small live dashboard around its JSON logs. Cowrie listens on port 22, a Python service follows the log and streams events over WebSockets, and Nginx serves the frontend. The whole thing currently runs on a 1 vCPU / 1 GB Debian VPS.
The dashboard groups activity by source IP, with individual SSH sessions nested underneath. It shows authentication attempts, commands, SSH client fingerprints, file writes and downloads, and tunneling requests in real time.
Initially I thought the interesting part would be simply watching commands appear. After looking at the collected data, I realized that recurring behavior is much more interesting than individual events.
In one roughly 8-hour sample, the honeypot recorded about 1,950 sessions from 213 source IPs. 327 sessions reached command execution.
Some recurring patterns included:
- the same SSH public key being installed 152 times from 11 source IPs
- a system fingerprinting script that appears designed to distinguish a real shell from a honeypot
- a downloader requesting payloads for several CPU architectures
- attempts to use SSH forwarding as a proxy
- distributed credential probes that connect, test one value, and immediately disconnect
This also showed me that grouping activity only by IP isn't enough. Several apparently different sources can use the same SSH client fingerprint, command sequence, public key, or downloaded artifact and probably belong to the same automated campaign.
At the moment this is primarily a live log viewer. Some directions I am considering are:
- automatic classification of sessions as scanning, credential probing, reconnaissance, persistence, downloading, or tunneling
- clustering activity into campaigns using HASSH fingerprints, command sequences, SSH keys, and artifact hashes
- historical statistics and searchable sessions
- support for multiple distributed honeypot sensors
- publishing the collector and dashboard code
The public stream currently includes source IPs, attempted credentials, and commands. I added a notice explaining that an IP may belong to a compromised machine, proxy, VPN, or scanner, but I am still thinking through the privacy and responsible-disclosure tradeoffs.
Cowrie's "login.success" events only mean that the honeypot accepted the credentials; they don't mean those credentials would work on a real server.
I'm trying to decide whether this should remain a simple live visualization or grow into a small analysis tool.
Which direction would make this project most useful or interesting to you? Are there other patterns or types of analysis that would be worth adding?
Some kind of source IP masking would be prudent. As you pointed out, some of those machines are compromised, and you aren't making their owners' lives any easier.
Bad actors might use the data you're publishing to fingerprint specific exploits to which the machines are vulnerable, multiplying the problem.
If producing an IP blacklist is one of your aims, divorcing it from any specific traffic would be more responsible.
You may also want to consider the risk traffic from compromised machines could leak PII (eg. say a script tried to use you as a relay to exfiltrate data) - and the ethical and legal consequences. A filter for SIN, credit cards, etc. would be a basic table-stakes mitigation step.
> Some kind of source IP masking would be prudent. As you pointed out, some of those machines are compromised, and you aren't making their owners' lives any easier.
Hard for me to find much sympathy for negligent users who unintentionally allowed their home computers or phones to join a malicious botnet, or their ISPs who aren't stopping the activity. Even if it is my own grandma's PC.
I agree about the content though, there probably are a lot of actually innocent victims' personal information in the traffic itself.
Easy for you to say, assuming your PC is clean. I don't think negligent is the right word though. Ignorant maybe? Or some form of naivety? The negligence might be on software or hardware vendors, but grandma isn't to blame for the problem.
Software providers generally lack a duty to their clients to create and sell secure software. Further, generally, when you get hacked, there is only an interrupted causal chain between the software and your loss. Interrupting that chain is the intervening superseding cause of a criminal third-party. Finally, no states allow punitive damages, absent gross negligence in a software context.
when you read or are told not to click on that link in the e-mail, or open the attachment, you should fire up your monitor while you are clicking on the links.
it might be interesting to have an eye on this while you are talking to the phone scammer.
We don’t have static IPs at home in Romania. A restart of the router will just give that person another public IP and they won’t notice any repercussions.
They are leaking their IP on the internet! Big security no-no. They'll need to download a lot more ram to deal with all the hackers coming for them.
A data broker is going to correlate this IP with "never gonna give you up" as an ideological statement about his drug dealings. They'll be receiving weird ads for weeks!
>Nah, Spur (a company tracking residential proxies) doesn't flag it at all.
I looked into it and so far as I can tell it works off a blacklist system, rather than any sort of automatic analysis (eg. TCP or MTU fingerprinting). If you set up a "residential proxy" in the form of a home VPN, it won't be detected. It also means the detection is only as good as whatever their backlist source is. If it's a niche provider, it might not get picked up at all.
They're not doing a very good job at it, tried a few disposable free residential proxies - not flagged. Tried my CGNAT home connection - flagged. My phone connection - also flagged.
> Tried my CGNAT home connection - flagged. My phone connection - also flagged.
Why does that mean they're doing a bad job? Since both are CGNAT, you're sharing the IP with lots of other people, and it's not unlikely that one of your network neighbors is infected.
I'm already working on truncating long values and grouping events by source. The next step will probably be rate limiting noisy sources and separating likely human test traffic from recurring automated behavior.
The recurring bot patterns are the part I ultimately want the interface to surface, rather than forcing visitors to inspect every raw event.
I'm currently fighting this battle.
As of this morning:
However, I have statistics for the CIDRs based on their whois record that look like:
CIDRs used: 1255
Already cached: 1252
Skipped uncached targets: 0
IPs scanned total: 985300
Estimated throttled wait: 0.10 minutes
== Country codes ==
Metric: Top 10 of 90 unique country codes
Total: 1183 country codes total and 90 unique country codes in 1255 targets
== Regions ==Metric: Top 10 of 29 unique regions
Total: 334 regions total and 29 unique regions in 1255 targets
== Origin ASNs ==Metric: Top 10 of 382 unique origin ASNs
Total: 805 origin ASNs total and 382 unique origin ASNs in 1255 targets
== Netnames ==Metric: Top 10 of 630 unique netnames
Total: 1157 netnames total and 630 unique netnames in 1255 targets
== Org names ==Metric: Top 10 of 222 unique org names
Total: 703 org names total and 222 unique org names in 1255 targets
== Organizations ==Metric: Top 10 of 236 unique organizations
Total: 691 organizations total and 236 unique organizations in 1255 targets
== Domains ==Metric: Top 10 of 534 unique domains
Total: 2581 domains total and 534 unique domains in 1255 targets
I deleted the (abuse) mail section. Because. 99% of the IPs are IPv4. In the IPset are mostly /32 but also a lot of ~/24 and rarely ~/16 segments. RIPE, ARIN and APNIC comes into play because some CIDR blocks are somewhat generously sized and block multiple network segments belonging to different organizations at the same time. E.g. this hides BR from the stats (because the ipset mostly bans every provider from BR).Some time ago I did a little experiment by running `nc -l -p 23` (telnet) which connects the next incoming telnet connection to your console. Type in a simulated prompt like Password: or # and it'll be buffered until the connection comes in. Then see what the scanner sends.
It’s too bad that ssh doesn’t carry sound. A MIDI-style rendition of the song would really tie it all together.
I maintain several web servers and kept seeing a constant stream of SSH login attempts. At some point I became curious: what do these bots actually try to do after they get in?
I set up a Cowrie SSH honeypot and built a small live dashboard around its JSON logs. Cowrie listens on port 22, a Python service follows the log and streams events over WebSockets, and Nginx serves the frontend. The whole thing currently runs on a 1 vCPU / 1 GB Debian VPS.
The dashboard groups activity by source IP, with individual SSH sessions nested underneath. It shows authentication attempts, commands, SSH client fingerprints, file writes and downloads, and tunneling requests in real time.
Initially I thought the interesting part would be simply watching commands appear. After looking at the collected data, I realized that recurring behavior is much more interesting than individual events.
In one roughly 8-hour sample, the honeypot recorded about 1,950 sessions from 213 source IPs. 327 sessions reached command execution.
Some recurring patterns included:
- the same SSH public key being installed 152 times from 11 source IPs - a system fingerprinting script that appears designed to distinguish a real shell from a honeypot - a downloader requesting payloads for several CPU architectures - attempts to use SSH forwarding as a proxy - distributed credential probes that connect, test one value, and immediately disconnect
This also showed me that grouping activity only by IP isn't enough. Several apparently different sources can use the same SSH client fingerprint, command sequence, public key, or downloaded artifact and probably belong to the same automated campaign.
At the moment this is primarily a live log viewer. Some directions I am considering are:
- automatic classification of sessions as scanning, credential probing, reconnaissance, persistence, downloading, or tunneling - clustering activity into campaigns using HASSH fingerprints, command sequences, SSH keys, and artifact hashes - historical statistics and searchable sessions - support for multiple distributed honeypot sensors - publishing the collector and dashboard code
The public stream currently includes source IPs, attempted credentials, and commands. I added a notice explaining that an IP may belong to a compromised machine, proxy, VPN, or scanner, but I am still thinking through the privacy and responsible-disclosure tradeoffs.
Cowrie's "login.success" events only mean that the honeypot accepted the credentials; they don't mean those credentials would work on a real server.
I'm trying to decide whether this should remain a simple live visualization or grow into a small analysis tool.
Which direction would make this project most useful or interesting to you? Are there other patterns or types of analysis that would be worth adding?
Bad actors might use the data you're publishing to fingerprint specific exploits to which the machines are vulnerable, multiplying the problem.
If producing an IP blacklist is one of your aims, divorcing it from any specific traffic would be more responsible.
You may also want to consider the risk traffic from compromised machines could leak PII (eg. say a script tried to use you as a relay to exfiltrate data) - and the ethical and legal consequences. A filter for SIN, credit cards, etc. would be a basic table-stakes mitigation step.
Hard for me to find much sympathy for negligent users who unintentionally allowed their home computers or phones to join a malicious botnet, or their ISPs who aren't stopping the activity. Even if it is my own grandma's PC.
I agree about the content though, there probably are a lot of actually innocent victims' personal information in the traffic itself.
it might be interesting to have an eye on this while you are talking to the phone scammer.
The aggregations of popular logins and IP locations seem interesting.
Try fingerprinting the behaviour in the sessions. Over time you should be able to distinguish between various automated tools and live people.
A data broker is going to correlate this IP with "never gonna give you up" as an ideological statement about his drug dealings. They'll be receiving weird ads for weeks!
He's most likely just not very smart.
I looked into it and so far as I can tell it works off a blacklist system, rather than any sort of automatic analysis (eg. TCP or MTU fingerprinting). If you set up a "residential proxy" in the form of a home VPN, it won't be detected. It also means the detection is only as good as whatever their backlist source is. If it's a niche provider, it might not get picked up at all.
Where are you finding free residential proxies?
> Tried my CGNAT home connection - flagged. My phone connection - also flagged.
Why does that mean they're doing a bad job? Since both are CGNAT, you're sharing the IP with lots of other people, and it's not unlikely that one of your network neighbors is infected.