``` Filename: 111-local-traffic-priority.txt Title: Prioritizing local traffic over relayed traffic Author: Roger Dingledine Created: 14-Mar-2007 Status: Closed Implemented-In: 0.2.0.x Overview: We describe some ways to let Tor users operate as a relay and enforce rate limiting for relayed traffic without impacting their locally initiated traffic. Motivation: Right now we encourage people who use Tor as a client to configure it as a relay too ("just click the button in Vidalia"). Most of these users are on asymmetric links, meaning they have a lot more download capacity than upload capacity. But if they enable rate limiting too, suddenly they're limited to the same download capacity as upload capacity. And they have to enable rate limiting, or their upstream pipe gets filled up, starts dropping packets, and now their net connection doesn't work even for non-Tor stuff. So they end up turning off the relaying part so they can use Tor (and other applications) again. So far this hasn't mattered that much: most of our fast relays are being operated only in relay mode, so the rate limiting makes sense for them. But if we want to be able to attract many more relays in the future, we need to let ordinary users act as relays too. Further, as we begin to deploy the blocking-resistance design and we rely on ordinary users to click the "Tor for Freedom" button, this limitation will become a serious stumbling block to getting volunteers to act as bridges. The problem: Tor implements its rate limiting on the 'read' side by only reading a certain number of bytes from the network in each second. If it has emptied its token bucket, it doesn't read any more from the network; eventually TCP notices and stalls until we resume reading. But if we want to have two classes of service, we can't know what class a given incoming cell will be until we look at it, at which point we've already read it. Some options: Option 1: read when our token bucket is full enough, and if it turns out that what we read was local traffic, then add the tokens back into the token bucket. This will work when local traffic load alternates with relayed traffic load; but it's a poor option in general, because when we're receiving both local and relayed traffic, there are plenty of cases where we'll end up with an empty token bucket, and then we're back where we were before. More generally, notice that our problem is easy when a given TCP connection either has entirely local circuits or entirely relayed circuits. In fact, even if they are both present, if one class is entirely idle (none of its circuits have sent or received in the past N seconds), we can ignore that class until it wakes up again. So it only gets complex when a single connection contains active circuits of both classes. Next, notice that local traffic uses only the entry guards, whereas relayed traffic likely doesn't. So if we're a bridge handling just a few users, the expected number of overlapping connections would be almost zero, and even if we're a full relay the number of overlapping connections will be quite small. Option 2: build separate TCP connections for local traffic and for relayed traffic. In practice this will actually only require a few extra TCP connections: we would only need redundant TCP connections to at most the number of entry guards in use. However, this approach has some drawbacks. First, if the remote side wants to extend a circuit to you, how does it know which TCP connection to send it on? We would need some extra scheme to label some connections "client-only" during construction. Perhaps we could do this by seeing whether any circuit was made via CREATE_FAST; but this still opens up a race condition where the other side sends a create request immediately. The only ways I can imagine to avoid the race entirely are to specify our preference in the VERSIONS cell, or to add some sort of "nope, not this connection, why don't you try another rather than failing" response to create cells, or to forbid create cells on connections that you didn't initiate and on which you haven't seen any circuit creation requests yet -- this last one would lead to a bit more connection bloat but doesn't seem so bad. And we already accept this race for the case where directory authorities establish new TCP connections periodically to check reachability, and then hope to hang up on them soon after. (In any case this issue is moot for bridges, since each destination will be one-way with respect to extend requests: either receiving extend requests from bridge users or sending extend requests to the Tor server, never both.) The second problem with option 2 is that using two TCP connections reveals that there are two classes of traffic (and probably quickly reveals which is which, based on throughput). Now, it's unclear whether this information is already available to the other relay -- he would easily be able to tell that some circuits are fast and some are rate limited, after all -- but it would be nice to not add even more ways to leak that information. Also, it's less clear that an external observer already has this information if the circuits are all bundled together, and for this case it's worth trying to protect it. Option 3: tell the other side about our rate limiting rules. When we establish the TCP connection, specify the different policy classes we have configured. Each time we extend a circuit, specify which policy class that circuit should be part of. Then hope the other side obeys our wishes. (If he doesn't, hang up on him.) Besides the design and coordination hassles involved in this approach, there's a big problem: our rate limiting classes apply to all our connections, not just pairwise connections. How does one server we're connected to know how much of our bucket has already been spent by another? I could imagine a complex and inefficient "ok, now you can send me those two more cells that you've got queued" protocol. I'm not sure how else we could do it. (Gosh. How could UDP designs possibly be compatible with rate limiting with multiple bucket sizes?) Option 4: put both classes of circuits over a single connection, and keep track of the last time we read or wrote a high-priority cell. If it's been less than N seconds, give the whole connection high priority, else give the whole connection low priority. Option 5: put both classes of circuits over a single connection, and play a complex juggling game by periodically telling the remote side what rate limits to set for that connection, so you end up giving priority to the right connections but still stick to roughly your intended bandwidthrate and relaybandwidthrate. Option 6: ? Prognosis: Nick really didn't like option 2 because of the partitioning questions. I've put option 4 into place as of Tor 0.2.0.3-alpha. In terms of implementation, it will be easy: just add a time_t to or_connection_t that specifies client_used (used by the initiator of the connection to rate limit it differently depending on how recently the time_t was reset). We currently update client_used in three places: - command_process_relay_cell() when we receive a relay cell for an origin circuit. - relay_send_command_from_edge() when we send a relay cell for an origin circuit. - circuit_deliver_create_cell() when send a create cell. We could probably remove the third case and it would still work, but hey. ```