Tor / Onion Routing[Tor] [Onion Routing]
Tor and Onion Routing are both anonymizing proxy networks, allowing people to tunnel out through their low latency mix network. The two primary differences between Tor / Onion-Routing and I2P are again related to differences in the threat model and the out-proxy design (though Tor supports hidden services as well). In addition, Tor takes the directory-based approach - providing a centralized point to manage the overall 'view' of the network, as well as gather and report statistics, as opposed to I2P's distributed network database and peer selection.
The I2P/Tor outproxy functionality does have a few substantial weaknesses against certain attackers - once the communication leaves the mixnet, global passive adversaries can more easily mount traffic analysis. In addition, the outproxies have access to the cleartext of the data transferred in both directions, and outproxies are prone to abuse, along with all of the other security issues we've come to know and love with normal Internet traffic.
However, many people don't need to worry about those situations, as they are outside their threat model. It is, also, outside I2P's (formal) functional scope (if people want to build outproxy functionality on top of an anonymous communication layer, they can). In fact, some I2P users currently take advantage of Tor to outproxy.
Comparação para Terminologia de Tor e I2P
While Tor and I2P are similar in many ways, much of the terminology is different.
|Cliente||Roteador ou Cliente|
|Servidor de Diretoria||Floodfill Router|
|Entry Guards||Fast Peers|
|Nodo de Entrada||Inproxy|
|Nodo de Saída||Proxy de saída|
|Serviço Oculto||Serviço Oculto, Eepsite or Destination|
|Hidden Service Descriptor||LeaseSet|
|Introduction point||Ponto de entrada|
|Onion Proxy||I2PTunnel Client (more or less)|
|Onion Service||Serviço Oculto, Eepsite or Destination|
|Rendezvous Point||somewhat like Inbound Gateway + Outbound Endpoint|
|Descritor do Roteador||Informação do Roteador|
Benefícios do Tor sobre I2P
- Much bigger user base; much more visibility in the academic and hacker communities; benefits from formal studies of anonymity, resistance, and performance; has a non-anonymous, visible, university-based leader
- Has already solved some scaling issues I2P has yet to address
- Has significant funding
- Has more developers, including several that are funded
- More resistant to state-level blocking due to TLS transport layer and bridges (I2P has proposals for "full restricted routes" but these are not yet implemented)
- Big enough that it has had to adapt to blocking and DOS attempts
- Designed and optimized for exit traffic, with a large number of exit nodes
- Better documentation, has formal papers and specifications, better website, many more translations
- More efficient with memory usage
- Tor client nodes have very low bandwidth overhead
- Centralized control reduces the complexity at each node and can efficiently address Sybil attacks
- A core of high capacity nodes provides higher throughput and lower latency
- C, não Java (ewww)
Benefícios do I2P sobre Tor
- Designed and optimized for hidden services, which are much faster than in Tor
- Totalmente distribuído e organização automática
- Peers are selected by continuously profiling and ranking performance, rather than trusting claimed capacity
- Floodfill peers ("directory servers") are varying and untrusted, rather than hardcoded
- Small enough that it hasn't been blocked or DOSed much, or at all
- Peer-to-peer friendly
- Packet switched instead of circuit switched
- implicit transparent load balancing of messages across multiple peers, rather than a single path
- resilience vs. failures by running multiple tunnels in parallel, plus rotating tunnels
- scale each client's connections at O(1) instead of O(N) (Alice has e.g. 2 inbound tunnels that are used by all of the peers Alice is talking with, rather than a circuit for each)
- Unidirectional tunnels instead of bidirectional circuits, doubling the number of nodes a peer has to compromise to get the same information. Counter-arguments and further discussion here.
- Protection against detecting client activity, even when an attacker is participating in the tunnel, as tunnels are used for more than simply passing end to end messages (e.g. netDb, tunnel management, tunnel testing)
- Tunnels in I2P are short lived, decreasing the number of samples that an attacker can use to mount an active attack with, unlike circuits in Tor, which are typically long lived.
- I2P APIs are designed specifically for anonymity and security, while SOCKS is designed for functionality.
- Essentially all peers participate in routing for others
- The bandwidth overhead of being a full peer is low, while in Tor, while client nodes don't require much bandwidth, they don't fully participate in the mixnet.
- Integrated automatic update mechanism
- Ambos os transportes TCP e UDP
- Java, não C (ewww)
Outros benefícios do i2P mas ainda não implementados
... e talvez não sejam implementados, por isso, não conte com eles!
- Defense vs. message count analysis by garlic wrapping multiple messages
- Defense vs. long term intersection by adding delays at various hops (where the delays are not discernible by other hops)
- Various mixing strategies at the tunnel level (e.g. create a tunnel that will handle 500 messages / minute, where the endpoint will inject dummy messages if there are insufficient messages, etc)