Hate to rain on the Linux parade here, but didn't the article say: "There are no ways to prevent such attacks except when the user's VPN runs on Android." and that Linux was just as vulnerable as Windows?
Interestingly, Android is the only operating system that fully immunizes VPN apps from the attack because it doesn't implement option 121. For all other OSes, there are no complete fixes. When apps run on Linux there’s a setting that minimizes the effects, but even then TunnelVision can be used to exploit a side channel that can be used to de-anonymize destination traffic and perform targeted denial-of-service attacks.
So for this attack to work, the attacker needs to be able to run a malicious DHCP server on the target machine’s network.
Meaning they need to have already compromised your local network either physically in person or by compromising a device on that network. If you’ve gotten that far you can already do a lot of damage without this attack.
For the average person this is yet another non-issue. But if you regularly use a VPN over untrusted networks like a hotel or coffee shop wifi then, in theory, an attacker could get your traffic to route outside the VPN tunnel.
Not all VPN traffic. Only traffic that would be routable without a VPN.
This works by tricking the computer into routing traffic to the attacker’s gateway instead of the VPN’s gateway. It doesn’t give the attacker access to the VPN gateway.
So traffic intended for a private network that is only accessible via VPN (like if you were connecting to a corporate network for example) wouldn’t be compromised. You simply wouldn’t be able to connect through the attacker’s gateway to the private network, and there wouldn’t be traffic to intercept.
This attack doesn’t break TLS encryption either. Anything you access over https (which is the vast majority of the internet these days) would still be just as encrypted as if you weren’t using a VPN.
For most people, in most scenarios, this amount to a small invasion of privacy. Our hypothetical malicious coffee shop could tell the ip addresses of websites you’re visiting, but probably not what you’re doing on those websites, unless it was an insecure website to begin with. Which is the case with or with VPN.
For some people or some situations that is a MASSIVE concern. People who use VPNs to hide what they’re doing from state level actors come to mind.
But for the average person who’s just using a VPN because they’re privacy conscious, or because they’re location spoofing. This is not going to represent a significant risk.
The thing is that in most cases you don’t need a VPN to protect yourself on a public network. The ubiquity of TLS on the internet already does a great job of that. Using a VPN on a public network for privacy and security reasons amounts to little more than the obfuscation of which sites you’re visiting, and some fallback protection against improperly configured websites. So while I agree it isn’t entirely a non-issue, it definitely isn’t as big of an issue as one might assume given the scary wording of the headline and article.
Not quite, this could be exploited by telecom providers when using mobile data. Also using a VPN for networks you DON'T control is one of the more popular uses of the things
As I mentioned in my other comment, this wouldn’t let an attacker eavesdrop on traffic on a VPN to a private corporate network by itself. It has to be traffic that is routable without the VPN.
No. Any device that implements a certain DHCP feature is vulnerable. Linux doesn't support it, because most Linux systems don't even use DHCP at all let alone this edge case feature. And Android doesn't support it because it inherited the Linux network stack.
I would bet some Linux systems are vulnerable, just not with the standard network packages installed. If you're issued a Linux laptop for work, wouldn't be surprised if it has a package that enables this feature. It essentially gives sysadmins more control over how packets are routed for every computer on the LAN.
WTF are you smoking? WTF is wrong with you that you think such a dumb claim would go unscrutinized? I would play Russian roulette on the chances of a random Linux installation on a random network talking DHCP.
Edit, in case being charitable helps: DNS and IP address allocation aren't the only things that happen over DHCP. And even then the odds are overwhelming that those are being broadcast that way.
If your LAN is already compromised with a rogue DHCP server, you've got bigger problems than them intercepting just VPN traffic. They can man in the middle all of your non-encrypted traffic. While this is bad, it's not a scenario most people will run into.
The problem isn't them being in you LAN. It's about going to an untrusted network (eg Starbucks, hotel) and connecting to your VPN, boom, now your VPN connection is compromised.
The other comment already covers the fact that VPN should be useful exactly when you are connected to untrusted LANs. I want to add that also the main point of your comment is anyway imprecise. You don't need a compromise DHCP, you just need another machine who spoofs being a DHCP. Not all networks have proper measures in place for these attacks, especially when we are talking wireless (for example, block client-to-client traffic completely). In other words, there is quite a middle-ground between a compromised router (which does DHCP in most cases) and just having a malicious device connected to the network.
To be fair, any proper VPN setup that only relies on the routing table like this is flawed to begin with.
If the VPN program dies or the network interface disappears, the routes are removed aswell, allowing traffic to leave the machine without the VPN.
So it is already a good practice to block traffic where it shouldnt go (or even better, only allowing it where it should).
Many VPN-Programs by Providers already have settings to enable this to prevent "leaking".
My understanding is that if you run a rogue discoverable DHCP server in a local network with a particular set of options set and hyper-specific routing rules, you can clobber the routing rules set by the VPN software on any non-Android device, and route all traffic from those devices through arbitrary midpoints that you control.
But IANANE (I am not a network engineer) so please correct my misinterpretations.
(obligatory I'm not a network surgeon this is likely not perfectly correct)
The article mentions network interfaces, DHCP and gateways so real quick: a network interface usually represents a physical connection to a network, like an Ethernet port or a WiFi card. DHCP is a protocol that auto configured network routes and addresses once a physical connection is established, like when you jack in via an ethernet cable, it tells you the IP address you should go by, the range of IP address on the network you've connected to, where you can resolve domain names to IP addresses. It also tells you the address of a default gateway to route traffic to, if you're trying to reach something outside of this network.
You can have more than one set of this configuration. Your wired network might tell you that your an address is 10.0.0.34, anything that starts with 10.0.0. is local, and to talk to 10.0.0.254 if you're trying to get to anything else. If at the same time you also connect to a wireless network, that might tell you that your address is 192.168.0.69, 192.168.0.* is your local network, and 192.168.0.254 is your gateway out. Now your computer wants to talk to 4.2.2.2. Should it use the wireless interface and go via 192.168.0.254? or the wired one and use 10.0.0.254? Your os has a routing table that includes both of those routes, and based on the precedence of the entries in it, it'll pick one.
VPN software usually works by creating a network interface on your computer, similar to an interface to a WiFi card, but virtual. It then asks the OS to route all network traffic, through the new interface it created. Except of course traffic from the VPN software, because that still needs to get out to the VPN provider (let's say, at 1.3.3.7) via real Internet.
So if you're following along at home, your routing table at this point might look like this:
traffic to 1.3.3.7 should go to 10.0.0.254 via the wired interface
all traffic should go to the VPN interface
traffic to 10.0.0.* should go to the wired interface
all traffic should go to 10.0.0.254 via the wired interface
traffic to 192.168.0.* should go to the wireless interface
all traffic should go to 192.168.0.254 via the wireless interface
whenever your os wants to send network packets, it'll go down this list of rules until one applies. With that VPN turned on, most of the time, only those two first rules will ever apply.
If I'm reading the article correctly, what this attack does, is run a DHCP server, that when handing out routing rules, will send one with a flag that causes, for example, the last two rules to be placed at the top of the list instead of the bottom. Your VPN will still be on, the configuration it's requested the OS to make would still be in place, and yet all your traffic will be routed out to this insecure wireless network that's somehow set itself as the priority route over anything else.
That actually lays it out incredibly well for me. So in practice, what would I need to look out for as a wired desktop Ubuntu user with mullvad? It's sounding like this is going to be an issue on public networks, is this something my isp can do to me at home?
I think this is a good enough reason to actually put in some effort to phase out ipv4 and dhcp. There shouldn't be a way for some random node on the network to tell my node what device to route traffic over. Stateless ipv6 for the win.
So if they are changing routes by using DHCP options, perhaps this could be exploited by telecom insiders when you are using mobile data, because your mobile data IP could be assigned by a DHCP server on the telecom network. If you're at home on wifi, then you can control your own DHCP server to prevent that.
The attack vector described in the article uses the VPN client machine's host network, i.e. the local network the device is attached to. They don't discuss the DHCP server of the VPN provider.
By pushing routes that are more specific than a /0 CIDR range that most VPNs use, we can make routing rules that have a higher priority than the routes for the virtual interface the VPN creates.
Most traffic gets sent through a VPN only because of a default gateway (set by the VPN) in the client's routing table. If the client's ISP were to have their DHCP server set one or more specific routes that are broad enough to cover most of the global address space, they would effectively override that default gateway. I believe that's the scenario described in the article.
Note that the "ISP" here could be a mobile operator, an internet cafe, an airport, someone running a wifi access point that looks like the airport's, or a guest on the same local network running an unauthorized DHCP server.
Most VPN providers don't use DHCP. OpenVPN emulates and hooks DHCP requests client-side to hand the OS the IP it got over the OpenVPN protocol in a more standard way (unless you use Layer 2 tunnels which VPN providers don't because it's useless for that use case). WireGuard doesn't support DHCP at all and it always comes from configuration.
The attack vector here seems to be public WiFi like coffee shops, airports, hotels and whatnot. The places you kinda do want to use a VPN.
On those, if they're not configured well such as coffee shops using consumer grade WiFi routers, an attacker on the same WiFi can respond to the DHCP request faster than the router or do an ARP spoof attack. The attacker can proxy the DHCP request to make sure you get a valid IP but add extra routes on top.
To execute this you need a DHCP server on the network.... But any admin worth his salt has a config on the switch to limit DHCP traffic to a designated server.
Seems extremely difficult to pull off in any corporate environment
For shits and giggles I used to sit on those wifis and run a mitm...I would replace all images with the troll face meme...then sit back and watch the confusion. So ya
That's why half decent VPN apps also add firewall rules to prevent leakage. Although nothing can beat Linux and shoving the real interface in a namespace so it's plainly not available to anything except the VPN process.
Yes, I don't agree with the no way to mitigate statement.
I suspect on windows the only real defence is something like.
Check if the network has suspicious multiple routes setup from the DHCP
If so, either use the IP/Mask/Gateway with manual IP config (to not receive the CIDR routes) or steer clear of an at best questionable network entirely.
Maybe use the windows firewall to block all traffic outbound EXCEPT from the firewall program (with perhaps exceptions for local networks as per below linux example). For whatever reason the windows firewall doesn't seem to have a way to specify an interface. But you can specify a program.
I did look for some way to control Window's handling of DHCP options. But it seems there isn't anything obvious to limit this otherwise. I do not know if the windows firewall has this kind of fine-grained control with its own fire
For linux, I used to have my own blackout firewall rules. That only allowed the specific LAN range (for mobile use you could include all RFC1918 ranges) and the specific VPN IP out of the internet facing interface. Only the VPN interface could otherwise access the internet.
Some providers have managed to make split tunnelling work fine so those I suspect are not affected because they override the routing at the driver level. It's really only the kinda lame OpenVPN wrappers that would be affected. When you have the custom driver, you can affect the routing. It's been a while since I've tested this stuff on Windows since obviously I haven't been paid to do that for 6 years, but yeah I don't even buy that all providers are affected and that it's unfixable. We had workarounds for that when I joined PIA already so it's probably been a known thing for at least a decade.
The issues we had is sometimes you could get the client to forget to remove the firewall rules or to add back the routes and it would break people's internet entirely. Not great but a good problem to have in context.
I use option 121 as part of my work, though I am not an expert on DHCP. This attack does make sense to me and it would be hard to work around given the legitimate uses for that option.
If i get this right, that attack only works before the tunnel is initiated (i.e. traffic encrypted), if the hosts is compromised, right? No danger from untrusted points inbetween, right?
This technique can also be used against an already established VPN connection once the VPN user’s host needs to renew a lease from our DHCP server. We can artificially create that scenario by setting a short lease time in the DHCP lease, so the user updates their routing table more frequently. In addition, the VPN control channel is still intact because it already uses the physical interface for its communication. In our testing, the VPN always continued to report as connected, and the kill switch was never engaged to drop our VPN connection.
Sounds to me like it totally works even after the tunnel has started.
Pushing a route also means that the network traffic will be sent over the same interface as the DHCP server instead of the virtual network interface. This is intended functionality that isn’t clearly stated in the RFC. Therefore, for the routes we push, it is never encrypted by the VPN’s virtual interface but instead transmitted by the network interface that is talking to the DHCP server. As an attacker, we can select which IP addresses go over the tunnel and which addresses go over the network interface talking to our DHCP server.
Ok, so double encrypted and authenticated traffic (TLS inside the VPN) would still be safe, and some stuff requiring an internal network origin via the VPN is safe (because the attacker can't break into the VPN connection and your client won't get the right response), but a ton of other traffic is exposed (especially unencrypted internal traffic on corporate networks, especially if it's also reachable without a VPN or if anything sends credentials in plaintext)
Researchers have devised an attack against nearly all virtual private network applications that forces them to send and receive some or all traffic outside of the encrypted tunnel designed to protect it from snooping or tampering.
TunnelVision, as the researchers have named their attack, largely negates the entire purpose and selling point of VPNs, which is to encapsulate incoming and outgoing Internet traffic in an encrypted tunnel and to cloak the user’s IP address.
The attack works by manipulating the DHCP server that allocates IP addresses to devices trying to connect to the local network.
A setting known as option 121 allows the DHCP server to override default routing rules that send VPN traffic through a local IP address that initiates the encrypted tunnel.
When apps run on Linux there’s a setting that minimizes the effects, but even then TunnelVision can be used to exploit a side channel that can be used to de-anonymize destination traffic and perform targeted denial-of-service attacks.
This remedy is problematic for two reasons: (1) a VPN user connecting to an untrusted network has no ability to control the firewall and (2) it opens the same side channel present with the Linux mitigation.
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(…) the entire purpose and selling point of VPNs, which is to encapsulate incoming and outgoing Internet traffic in an encrypted tunnel and to cloak the user’s IP address.
No. That is not the entire point of a VPN. That’s just what a few shady companies are claiming to scam uninformed users into paying for a useless service. The entire point of a VPN is to join a private network (i.e. a network that is not part of the Internet) over the public internet, such as connecting to your company network from home. Hence the name ‘virtual private network’.
There are very little, if any, benefits to using a VPN service to browse the public internet.
that works, but a regular SOCKS proxy should do. for HTTP even a HTTP proxy. many VPN providers offer them too, btw.. may help with mitigating this attack vector.
Encrypted VPN tunnels are ubiquitous in many industries for remote connection to private clouds. They are used by virtually every high functioning company in the world, and getting more common for mid and lower tier companies as well.
There's no real way to know if VPNs intended for the public are run the same as those intended for enterprise. Windows doesn't have a lot of the same BS in their enterprise versions that are in the personal ones. Even with the same software, it could just be a checkbox that the salesperson can check for big businesses with legal teams that read and enforce contracts.
I assume this is definitely the case for free VPNs, if any of those still exist. There might be some willing to donate bandwidth and compute resources for the good of others, but I'm sure there's more that pretend to do that but actually just sell the data or maybe just spy.
Tbh I wouldn't be surprised if this is also the case for TOR nodes. I wonder how many entry and exit points are run by the NSA or some other government entity. Or are just monitored. If you can monitor the entry and exit points, you can determine both the source and destination, and just match them together using the middle node address.
Same thing with proxies.
Paid VPNs could go either way. On the one hand, they could make more money if they are willing to sell out their users' privacy. On the other hand, that risks the entire thing falling apart if word gets out that it's not private, since that's the whole point of VPNs. I'm sure there's some good ones out there but I'm also sure that there's bad ones and wouldn't be surprised if some of the ones considered good are actually bad.
Maybe ones that run in Europe would be safer bets. Their business is at least able to run there with the privacy laws. Maybe they are skirting them and haven't been caught yet, maybe their data sales from other regions are profitable enough to support European operations without data sales, but if they are going for max greed and min risk, maybe they wouldn't operate there. Or maybe they just run things differently in the different regions to maximize global profits.