- cross-posted to:
- netsec
- secops
- [email protected]
- cross-posted to:
- netsec
- secops
- [email protected]
What are TunnelCrack vulnerabilities?
- Two widespread security vulnerabilities in VPNs can be abused by an adversary to leak traffic outside the VPN tunnel.
- The two vulnerabilities are called the LocalNet and ServerIP attack.
Summary of what VPNs are vulnerable to TunnelCrack
- VPNs for iPhones, iPads, MacBooks, and macOS are extremely likely to be vulnerable
- A majority of VPNs on Windows and Linux are vulnerable
- Android is the most secure with roughly one-quarter of VPN apps being vulnerable.
- Users generally decide which VPN protocol to adopt while creating the VPN tunnel, with common options being OpenVPN, WireGuard, or IPsec. As a result, the precise configuration of the client, and whether it is vulnerable to (variants of) our attacks, may depend on the chosen VPN server and protocol.
TunnelCrack Prevention
To prevent the attack, VPN clients should be updated to send all traffic through the VPN tunnel, except traffic generated by the VPN app itself.
How do the LocalNet and ServerIP attacks work?
LocalNet attack:
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The adversary acts as a malicious Wi-Fi or Ethernet network and tricks the victim into connecting to it.
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Once connected, the adversary assigns a public IP address and subnet to the victim.
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The adversary then tells the victim that the local network is using this subnet, which means that IP addresses in this range are directly reachable in the local network. When the victim now visits a website with an IP address in this range, the web request will be sent outside the protected VPN tunnel.
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66+ VPNs on five platforms were tested and found that all VPN apps on iOS are vulnerable. Additionally, all but one VPN client on macOS is vulnerable, on Windows a large majority of VPNs are vulnerable, and on Linux more than one-third are vulnerable. Interestingly, VPN apps on Android are typically the most secure, with one-quarter being vulnerable to the LocalNet attack.
ServerIP attack:
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The adversary abuses the observation that many VPNs don’t encrypt traffic towards the IP address of the VPN server. This is done to avoid re-encryption of packets.
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The adversary first spoofs the DNS reply for the VPN server to return the IP address of a website that they control. The victim will then connect with the VPN server at this IP address.
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To assure the victim still successfully creates a VPN connection, the adversary redirects this traffic to the real VPN server.
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While establishing the VPN connection, the victim will add a routing rule so that all traffic to the VPN server, in this case the spoofed IP address, is sent outside the VPN tunnel. When the victim now visits a website with the IP address of the VPN server, the web request is sent outside the protected VPN tunnel.
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Built-in VPN clients of Windows, macOS, and iOS are vulnerable. Android 12 and higher is not affected. A significant number of Linux VPNs are also vulnerable.
The first one is just split tunneling which is a design feature for most organizations using VPN, so any company paying for this for their employees, and many using stuff like OpenVPN explicitly want that feature for good reasons.
The second requires both intercepting DNS (which I think is getting harder all the time with DNSSEC etc) and you not using a server certificate to authenticate the actual VPN server (unless I really misunderstand what’s happening here). Most public VPN servers don’t seem to be configured to work as you say (not send traffic for their server / site over the tunnel) - at least OpenVPN with common configurations will send traffic over the tunnel as far as I’ve been able to determine. Some details to reproduce this would be helpful. The paper isn’t currently available, but I’m still wondering how they’re adding a static route to the client unless they can in fact terminate the VPN connection and pass back config rules different from the client config file.
Yeah I don’t quite see how this is supposed to work either. They say they send the traffic to the intercepting server and then forward it to the “real” VPN server to actually establish the connection. But unless they can actually crack any of the encryption, all they have is the encrypted traffic to and from the sever if I’m not mistaken … So what they do with that I’m unsure.
So having DNSSEC on the domain of the server prevents the second attack?
It narrows the chance of DNS interception but the second attack can be mitigated through certificate validation of the VPN server.
I think both attacks are actually DNS vulnerabilities from my reading of the paper which is now available. It has nothing whatsoever to do with VPNs, except in so far as you can abuse DNS to redirect traffic to a hostname somewhere else. I suppose the first attack does suggest that commercial VPN companies should update their configuration to require the non-routed IPs to be the local network unless otherwise overridden by the customer. That should completely kill the first attack from what I can tell. Customers can also just look at their route tables after connecting to a random wifi and see if it looks weird (the local net not being 192.168.0.0/24, 172.16-20.0.0/16[IIRC, google the range],10.0.0.0/8)…
The second attack still requires the attacker to control DNS, so again, is basically either the ISP or a rogue AP. I still think DNSSEC helps, DoH would help (but OSs don’t use this, and generally for good reason - we really really need PKI for DNS as the new standard IMHO, which I think DoH is trying to do), but also hardcoding the DNS server you use to a known good server (this might be hard, but like 1.1.1.1 is going to be harder to intercept) would stop it.
This is also why people say VPN doesn’t provide full security on it’s own (Though I question the ability to pull these attacks off in most practical situations - quite a lot depends on your threat model) and redirecting HTTPS traffic for instance outside the VPN leaks that you connected to that site, but none of the contents of the traffic.
I run a personal VPN on my DNS and I don’t know how to tell if I’m vulnerable.
But when I’m in a country like China, using 1.1.1.1 directly is sometimes an issue, China poisons the unencrypted DNS traffic and blocks encrypted traffic on known DNS servers
Given the threat model of a malicious state actor, what can I do?
Honestly - nothing . You need to not use the Internet for anything sensitive if a nation state is after your traffic, even moreso if you’re inside their network, even more so if it’s controlled as tightly as China does.
In the US you might hide among the other traffic if you really know what you’re doing and very careful. Especially if they’re not suspecting you and so aren’t directly targeting you. And that’s a big if. China blocks traffic so you just end up. Screwed.
That’s absolutely wrong, even China can’t get to my encrypted traffic, since I’m hiding it among the other encrypted traffic on port 443
Also, I’m not using encrypted client hello (banned in China), but it’s spoofed to a real domain of a real company so the GFW thinks I just really love that website
Ok, but now you’re masquerading as HTTPS. I was talking about most VPNs use known ports (openvpn port for instance). I also have heard a lot of external sites are blocked in China, so I was referencing that I would guess most commercial VPN servers get blocked also. If you’re running your own endpoint (not paying for a commercial service) and making it look like SSL, and China isn’t blocking that IP address outside the country at this time, then it should work, though I’d still worry about timing and network correlation attacks - if a nation state wanted to. There’s a lot of wiggle room in that if, and I wouldn’t put it past them to just backdoor your hardware on entry (or the US customs inspection either FWIW).
It’s just some AWS IP, these servers don’t have their own provider. So some commerical ones still work. But self-hosting is more predictable
The VPN also does padding to hide small packets like SYN/ACK. The access patterns are an issue, but they kind of just throttle you since that’s not a 100% tell.
My hardware is my phone and I keep it on my person, they haven’t touched that, thankfully