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641 lines
29 KiB
Plaintext
641 lines
29 KiB
Plaintext
$Id$
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Tor directory protocol for 0.1.1.x series
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0. Scope and preliminaries
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This document should eventually be merged into tor-spec.txt and replace
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the existing notes on directories.
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This is not a finalized version; what we actually wind up implementing
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may be very different from the system described here.
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0.1. Goals
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There are several problems with the way Tor handles directories right
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now:
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1. Directories are very large and use a lot of bandwidth.
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2. Every directory server is a single point of failure.
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3. Requiring every client to know every server won't scale.
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4. Requiring every directory cache to know every server won't scale.
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5. Our current "verified server" system is kind of nonsensical.
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6. Getting more directory servers adds more points of failure and
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worsens possible partitioning attacks.
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This design tries to solve every problem except problems 3 and 4, and to
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be compatible with likely eventual solutions to problems 3 and 4.
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1. Outline
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There is no longer any such thing as a "signed directory". Instead,
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directory servers sign a very compressed 'network status' object that
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lists the current descriptors and their status, and router descriptors
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continue to be self-signed by servers. Clients download network status
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listings periodically, and download router descriptors as needed. ORs
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upload descriptors relatively infrequently.
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There are multiple directory servers. Rather than doing anything
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complicated to coordinate themselves, clients simply rotate through them
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in order, and only use servers that most of the last several directory
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servers like.
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2. Router descriptors
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Router descriptors are as described in the current tor-spec.txt
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document.
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ORs SHOULD generate a new router descriptor whenever any of the
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following events have occurred:
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- A period of time (24 hrs by default) has passed since the last
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time a descriptor was generated.
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- A descriptor field other than bandwidth or uptime has changed.
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- Bandwidth has changed by more than +/- 50% from the last time a
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descriptor was generated, and at least a given interval of time (1
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hr by default) has passed since then.
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- Uptime has been reset.
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After generating a descriptor, ORs upload it to every directory
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server they know.
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The router descriptor format is unchanged from tor-spec.txt.
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3. Network status
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Directory servers generate, sign, and compress a network-status document
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as needed. As an optimization, they may rate-limit the number of such
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documents generated to once every few seconds. Directory servers should
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rate-limit at least to the point where these documents are generated no
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faster than once per second.
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The network status document contains a preamble, a set of router status
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entries, and a signature, in that order.
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We use the same meta-format as used for directories and router descriptors
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in "tor-spec.txt".
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The preamble contains:
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"network-status-version" -- A document format version. For this
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specification, the version is "2".
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"dir-source" -- The hostname, current IP address, and directory
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port of the directory server, separated by spaces.
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"fingerprint" -- A base16-encoded hash of the signing key's
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fingerprint, with no additional spaces added.
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"contact" -- An arbitrary string describing how to contact the
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directory server's administrator. Administrators should include at
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least an email address and a PGP fingerprint.
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"dir-signing-key" -- The directory server's public signing key.
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"client-versions" -- A comma-separated list of recommended client versions
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"server-versions" -- A comma-separated list of recommended server versions
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"published" -- The publication time for this network-status object.
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"dir-options" -- A set of flags separated by spaces:
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"Names" if this directory server performs name bindings
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The directory-options entry is optional; the others are required and must
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appear exactly once. The "network-status-version" entry must appear first;
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the others may appear in any order.
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For each router, the router entry contains: (This format is designed for
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conciseness.)
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"r" -- followed by the following elements, separated by spaces:
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- The OR's nickname,
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- A hash of its identity key, encoded in base64, with trailing =
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signs removed.
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- A hash of its most recent descriptor, encoded in base64, with
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trailing = signs removed.
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- The publication time of its most recent descriptor.
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- An IP
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- An OR port
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- A directory port (or "0" for none")
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"s" -- A series of space-separated status flags:
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"Exit" if the router is useful for building general-purpose exit
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circuits
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"Stable" if the router tends to stay up for a long time
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"Fast" if the router has high bandwidth
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"Running" if the router is currently usable
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"Named" if the router's identity-nickname mapping is canonical.
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"Valid" if the router has been 'validated'.
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The "r" entry for each router must appear first and is required. The
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's" entry is optional. Unrecognized flags, or extra elements on the
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"r" line must be ignored.
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The signature section contains:
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"directory-signature". A signature of the rest of the document using
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the directory server's signing key.
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We compress the network status list with zlib before transmitting it.
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4. Directory server operation
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By default, directory servers remember all non-expired, non-superseded OR
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descriptors that they have seen.
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For each OR, a directory server remembers whether the OR was running and
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functional the last time they tried to connect to it, and possibly other
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liveness information.
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Directory server administrators may label some servers or IPs as
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blacklisted, and elect not to include them in their network-status lists.
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Thus, the network-status list includes all non-blacklisted,
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non-expired, non-superseded descriptors for ORs that the directory has
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observed at least once to be running.
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Directory server administrators may decide to support name binding. If
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they do, then they must maintain a file of nickname-to-identity-key
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mappings, and try to keep this file consistent with other directory
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servers. If they don't, they act as clients, and report bindings made by
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other directory servers (name X is bound to identity Y if at least one
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binding directory lists it, and no directory binds X to some other Y'.)
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The authoritative network-status published by a host should be available at:
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http://<hostname>/tor/status/authority.z
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An authoritative network-status published by another host with fingerprint
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<F> should be available at:
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http://<hostname>/tor/status/fp/<F>.z
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An authoritative network-status published by other hosts with fingerprints
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<F1>,<F2>,<F3> should be available at:
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http://<hostname>/tor/status/fp/<F1>+<F2>+<F3>.z
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The most recent network-status documents from all known authoritative
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directories, concatenated, should be available at:
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http://<hostname>/tor/status/all.z
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The most recent descriptor for a server whose identity key has a
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fingerprint of <F> should be available at:
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http://<hostname>/tor/server/fp/<F>.z
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The most recent descriptors for servers have fingerprints <F1>,<F2>,<F3>
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should be available at:
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http://<hostname>/tor/server/fp/<F1>+<F2>+<F3>.z
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The most recent descriptor for this server should be at:
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http://<hostname>/tor/server/authority.z
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A concatenated set of the most recent descriptors for all known servers
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should be available at:
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http://<hostname>/tor/server/all.z
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For debugging, directories MAY expose non-compressed objects at URLs like
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the above, but without the final ".z".
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Clients MUST handle compressed concatenated information in two forms:
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- A concatenated list of zlib-compressed objects.
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- A zlib-compressed concatenated list of objects.
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Directory servers MAY generate either format: the former requires less
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CPU, but the latter requires less bandwidth.
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4.1. Caching
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Directory caches (most ORs) regularly download network status documents,
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and republish them at a URL based on the directory server's identity key:
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http://<hostname>/tor/status/<identity fingerprint>.z
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A concatenated list of all network-status documents should be available at:
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http://<hostname>/tor/status/all.z
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4.2. Compression
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5. Client operation
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Every OP or OR, including directory servers, acts as a client to the
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directory protocol.
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Each client maintains a list of trusted directory servers. Periodically
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(currently every 20 minutes), the client downloads a new network status. It
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chooses the directory server from which its current information is most
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out-of-date, and retries on failure until it finds a running server.
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When choosing ORs to build circuits, clients proceed as follows:
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- A server is "listed" if it is listed by more than half of the "live"
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network status documents the clients have downloaded. (A network
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status is "live" if it is the most recently downloaded network status
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document for a given directory server, and the server is a directory
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server trusted by the client, and the network-status document is no
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more than D (say, 10) days old.)
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- A server is "valid" is it is listed as valid by more than half of the
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"live" downloaded" network-status document.
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- A server is "running" if it is listed as running by more than
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half of the "recent" downloaded network-status documents.
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(A network status is "recent" if it was published in the last
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60 minutes. If there are fewer than 3 such documents, the most
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recently published 3 are "recent." If there are fewer than 3 in all,
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all are "recent.")
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Clients store network status documents so long as they are live.
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5.1. Scheduling network status downloads
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This download scheduling algorithm implements the approach described above
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in a relatively low-state fashion. It reflects the current Tor
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implementation.
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Clients maintain a list of authorities; each client tries to keep the same
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list, in the same order.
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Periodically, on startup, and on HUP, clients check whether they need to
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download fresh network status documents. The approach is as follows:
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- If we have under X network status documents newer than OLD, we choose a
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member of the list at random and try download XX documents starting
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with that member's.
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- Otherwise, if we have no network status documents newer than NEW, we
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check to see which authority's document we retrieved most recently,
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and try to retrieve the next authority's document. If we can't, we
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try the next authority in sequence, and so on.
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5.2. Managing naming
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In order to provide human-memorable names for individual server
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identities, some directory servers bind names to IDs. Clients handle
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names in two ways:
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If a client is encountering a name it has not mapped before:
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If all the "binding" networks-status documents the client has so far
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received same claim that the name binds to some identity X, and the
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client has received at least three network-status documents, the client
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maps the name to X.
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If a client is encountering a name it has mapped before:
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It uses the last-mapped identity value, unless all of the "binding"
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network status documents bind the name to some other identity.
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6. Remaining issues
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Client-knowledge partitioning is worrisome. Most versions of this don't
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seem to be worse than the Danezis-Murdoch tracing attack, since an
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attacker can't do more than deduce probable exits from entries (or vice
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versa). But what about when the client connects to A and B but in a
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different order? How bad can it be partitioned based on its knowledge?
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================================================================================
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Everything below this line is obsolete.
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--------------------------------------------------------------------------------
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Tor network discovery protocol
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0. Scope
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This document proposes a way of doing more distributed network discovery
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while maintaining some amount of admission control. We don't recommend
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you implement this as-is; it needs more discussion.
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Terminology:
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- Client: The Tor component that chooses paths.
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- Server: A relay node that passes traffic along.
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1. Goals.
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We want more decentralized discovery for network topology and status.
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In particular:
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1a. We want to let clients learn about new servers from anywhere
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and build circuits through them if they wish. This means that
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Tor nodes need to be able to Extend to nodes they don't already
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know about.
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1b. We want to let servers limit the addresses and ports they're
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willing to extend to. This is necessary e.g. for middleman nodes
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who have jerks trying to extend from them to badmafia.com:80 all
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day long and it's drawing attention.
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1b'. While we're at it, we also want to handle servers that *can't*
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extend to some addresses/ports, e.g. because they're behind NAT or
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otherwise firewalled. (See section 5 below.)
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1c. We want to provide a robust (available) and not-too-centralized
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mechanism for tracking network status (which nodes are up and working)
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and admission (which nodes are "recommended" for certain uses).
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2. Assumptions.
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2a. People get the code from us, and they trust us (or our gpg keys, or
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something down the trust chain that's equivalent).
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2b. Even if the software allows humans to change the client configuration,
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most of them will use the default that's provided. so we should
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provide one that is the right balance of robust and safe. That is,
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we need to hard-code enough "first introduction" locations that new
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clients will always have an available way to get connected.
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2c. Assume that the current "ask them to email us and see if it seems
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suspiciously related to previous emails" approach will not catch
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the strong Sybil attackers. Therefore, assume the Sybil attackers
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we do want to defend against can produce only a limited number of
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not-obviously-on-the-same-subnet nodes.
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2d. Roger has only a limited amount of time for approving nodes; shouldn't
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be the time bottleneck anyway; and is doing a poor job at keeping
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out some adversaries.
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2e. Some people would be willing to offer servers but will be put off
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by the need to send us mail and identify themselves.
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2e'. Some evil people will avoid doing evil things based on the perception
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(however true or false) that there are humans monitoring the network
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and discouraging evil behavior.
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2e''. Some people will trust the network, and the code, more if they
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have the perception that there are trustworthy humans guiding the
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deployed network.
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2f. We can trust servers to accurately report their characteristics
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(uptime, capacity, exit policies, etc), as long as we have some
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mechanism for notifying clients when we notice that they're lying.
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2g. There exists a "main" core Internet in which most locations can access
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most locations. We'll focus on it (first).
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3. Some notes on how to achieve.
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Piece one: (required)
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We ship with N (e.g. 20) directory server locations and fingerprints.
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Directory servers serve signed network-status pages, listing their
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opinions of network status and which routers are good (see 4a below).
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Dirservers collect and provide server descriptors as well. These don't
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need to be signed by the dirservers, since they're self-certifying
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and timestamped.
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(In theory the dirservers don't need to be the ones serving the
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descriptors, but in practice the dirservers would need to point people
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at the place that does, so for simplicity let's assume that they do.)
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Clients then get network-status pages from a threshold of dirservers,
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fetch enough of the corresponding server descriptors to make them happy,
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and proceed as now.
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Piece two: (optional)
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We ship with S (e.g. 3) seed keys (trust anchors), and ship with
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signed timestamped certs for each dirserver. Dirservers also serve a
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list of certs, maybe including a "publish all certs since time foo"
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functionality. If at least two seeds agree about something, then it
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is so.
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Now dirservers can be added, and revoked, without requiring users to
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upgrade to a new version. If we only ship with dirserver locations
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and not fingerprints, it also means that dirservers can rotate their
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signing keys transparently.
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But, keeping track of the seed keys becomes a critical security issue.
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And rotating them in a backward-compatible way adds complexity. Also,
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dirserver locations must be at least somewhere static, since each lost
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dirserver degrades reachability for old clients. So as the dirserver
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list rolls over we have no choice but to put out new versions.
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Piece three: (optional)
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Notice that this doesn't preclude other approaches to discovering
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different concurrent Tor networks. For example, a Tor network inside
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China could ship Tor with a different torrc and poof, they're using
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a different set of dirservers. Some smarter clients could be made to
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learn about both networks, and be told which nodes bridge the networks.
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...
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4. Unresolved issues.
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4a. How do the dirservers decide whether to recommend a server? We
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could have them do it based on contact from the human, but by
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assumptions 2c and 2d above, that's going to be less effective, and
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more of a hassle, as we scale up. Thus I propose that they simply
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do some basic automatic measuring themselves, starting with the
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current "are they connected to me" measurement, and that's all
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that is done.
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We could blacklist as we notice evil servers, but then we're in
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the same boat all the irc networks are in. We could whitelist as we
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notice new servers, and stop whitelisting (maybe rolling back a bit)
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once an attack is in progress. If we assume humans aren't particularly
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good at this anyway, we could just do automated delayed whitelisting,
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and have a "you're under attack" switch the human can enable for a
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while to start acting more conservatively.
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Once upon a time we collected contact info for servers, which was
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mainly used to remind people that their servers are down and could
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they please restart. Now that we have a critical mass of servers,
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I've stopped doing that reminding. So contact info is less important.
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4b. What do we do about recommended-versions? Do we need a threshold of
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dirservers to claim that your version is obsolete before you believe
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them? Or do we make it have less effect -- e.g. print a warning but
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never actually quit? Coordinating all the humans to upgrade their
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recommended-version strings at once seems bad. Maybe if we have
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seeds, the seeds can sign a recommended-version and upload it to
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the dirservers.
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4c. What does it mean to bind a nickname to a key? What if each dirserver
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does it differently, so one nickname corresponds to several keys?
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Maybe the solution is that nickname<=>key bindings should be
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individually configured by clients in their torrc (if they want to
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refer to nicknames in their torrc), and we stop thinking of nicknames
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as globally unique.
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4d. What new features need to be added to server descriptors so they
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remain compact yet support new functionality? Section 5 is a start
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of discussion of one answer to this.
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5. Regarding "Blossom: an unstructured overlay network for end-to-end
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connectivity."
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SECTION 5A: Blossom Architecture
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Define "transport domain" as a set of nodes who can all mutually name each
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other directly, using transport-layer (e.g. HOST:PORT) naming.
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Define "clique" as a set of nodes who can all mutually contact each other directly,
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using transport-layer (e.g. HOST:PORT) naming.
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Neither transport domains and cliques form a partition of the set of all nodes.
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Just as cliques may overlap in theoretical graphs, transport domains and
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cliques may overlap in the context of Blossom.
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In this section we address possible solutions to the problem of how to allow
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Tor routers in different transport domains to communicate.
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First, we presume that for every interface between transport domains A and B,
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one Tor router T_A exists in transport domain A, one Tor router T_B exists in
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transport domain B, and (without loss of generality) T_A can open a persistent
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connection to T_B. Any Tor traffic between the two routers will occur over
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this connection, which effectively renders the routers equal partners in
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bridging between the two transport domains. We refer to the established link
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between two transport domains as a "bridge" (we use this term because there is
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no serious possibility of confusion with the notion of a layer 2 bridge).
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Next, suppose that the universe consists of transport domains connected by
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persistent connections in this manner. An individual router can open multiple
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connections to routers within the same foreign transport domain, and it can
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establish separate connections to routers within multiple foreign transport
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domains.
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As in regular Tor, each Blossom router pushes its descriptor to directory
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servers. These directory servers can be within the same transport domain, but
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they need not be. The trick is that if a directory server is in another
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transport domain, then that directory server must know through which Tor
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routers to send messages destined for the Tor router in question.
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|
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Blossom routers can advertise themselves to other transport domains in two
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ways:
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(1) Directly push the descriptor to a directory server in the other transport
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|
domain. This probably works particularly well if the other transport domain is
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"the Internet", or if there are hard-coded directory servers in "the Internet".
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The router has the responsibility to inform the directory server about which
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routers can be used to reach it.
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|
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(2) Push the descriptor to a directory server in the same transport domain.
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This is the easiest solution for the router, but it relies upon the existence
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|
of a directory server in the same transport domain that is capable of
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|
communicating with directory servers in the remote transport domain. In order
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|
for this to work, some individual Tor routers must have published their
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|
descriptors in remote transport domains (i.e. followed the first option) in
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|
order to provide a link by which directory servers can communiate
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|
bidirectionally.
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|
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If all directory servers are within the same transport domain, then approach
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|
(1) is sufficient: routers can exist within multiple transport domains, and as
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|
long as the network of transport domains is fully connected by bridges, any
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|
router will be able to access any other router in a foreign transport domain
|
|
simply by extending along the path specified by the directory server. However,
|
|
we want the system to be truly decentralized, which means not electing any
|
|
particular transport domain to be the master domain in which entries are
|
|
published.
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|
|
|
This is the explanation for (2): in order for a directory server to share
|
|
information with a directory server in a foreign transport domain to which it
|
|
cannot speak directly, it must use Tor, which means referring to the other
|
|
directory server by using a router in the foreign transport domain. However,
|
|
in order to use Tor, it must be able to reach that router, which means that a
|
|
descriptor for that router must exist in its table, along with a means of
|
|
reaching it. Therefore, in order for a mutual exchange of information between
|
|
routers in transport domain A and those in transport domain B to be possible,
|
|
when routers in transport domain A cannot establish direct connections with
|
|
routers in transport domain B, then some router in transport domain B must have
|
|
pushed its descriptor to a directory server in transport domain A, so that the
|
|
directory server in transport domain A can use that router to reach the
|
|
directory server in transport domain B.
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|
|
|
Descriptors for Blossom routers are read-only, as for regular Tor routers, so
|
|
directory servers cannot modify them. However, Tor directory servers also
|
|
publish a "network-status" page that provide information about which nodes are
|
|
up and which are not. Directory servers could provide an additional field for
|
|
Blossom nodes. For each Blossom node, the directory server specifies a set of
|
|
paths (may be only one) through the overlay (i.e. an ordered list of router
|
|
names/IDs) to a router in a foreign transport domain. (This field may be a set
|
|
of paths rather than a single path.)
|
|
|
|
A new router publishing to a directory server in a foreign transport should
|
|
include a list of routers. This list should be either:
|
|
|
|
a. ...a list of routers to which the router has persistent connections, or, if
|
|
the new router does not have any persistent connections,
|
|
|
|
b. ...a (not necessarily exhaustive) list of fellow routers that are in the
|
|
same transport domain.
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|
|
|
The directory server will be able to use this information to derive a path to
|
|
the new router, as follows. If the new router used approach (a), then the
|
|
directory server will define the set of paths to the new router as union of the
|
|
set of paths to the routers on the list with the name of the last hop appended
|
|
to each path. If the new router used approach (b), then the directory server
|
|
will define the paths to the new router as the union of the set of paths to the
|
|
routers specified in the list. The directory server will then insert the newly
|
|
defined path into the field in the network-status page from the router.
|
|
|
|
When confronted with the choice of multiple different paths to reach the same
|
|
router, the Blossom nodes may use a route selection protocol similar in design
|
|
to that used by BGP (may be a simple distance-vector route selection procedure
|
|
that only takes into account path length, or may be more complex to avoid
|
|
loops, cache results, etc.) in order to choose the best one.
|
|
|
|
If a .exit name is not provided, then a path will be chosen whose nodes are all
|
|
among the set of nodes provided by the directory server that are believed to be
|
|
in the same transport domain (i.e. no explicit path). Thus, there should be no
|
|
surprises to the client. All routers should be careful to define their exit
|
|
policies carefully, with the knowledge that clients from potentially any
|
|
transport domain could access that which is not explicitly restricted.
|
|
|
|
SECTION 5B: Tor+Blossom desiderata
|
|
|
|
The interests of Blossom would be best served by implementing the following
|
|
modifications to Tor:
|
|
|
|
I. CLIENTS
|
|
|
|
Objectives: Ultimately, we want Blossom requests to be indistinguishable in
|
|
format from non-Blossom .exit requests, i.e. hostname.forwarder.exit.
|
|
|
|
Proposal: Blossom is a process that manipulates Tor, so it should be
|
|
implemented as a Tor Control, extending control-spec.txt. For each request,
|
|
Tor uses the control protocol to ask the Blossom process whether it (the
|
|
Blossom process) wants to build or assign a particular circuit to service the
|
|
request. Blossom chooses one of the following responses:
|
|
|
|
a. (Blossom exit node, circuit cached) "use this circuit" -- provides a circuit
|
|
ID
|
|
|
|
b. (Blossom exit node, circuit not cached) "I will build one" -- provides a
|
|
list of routers, gets a circuit ID.
|
|
|
|
c. (Regular (non-Blossom) exit node) "No, do it yourself" -- provides nothing.
|
|
|
|
II. ROUTERS
|
|
|
|
Objectives: Blossom routers are like regular Tor routers, except that Blossom
|
|
routers need these features as well:
|
|
|
|
a. the ability to open peresistent connections,
|
|
|
|
b. the ability to know whwther they should use a persistent connection to reach
|
|
another router,
|
|
|
|
c. the ability to define a set of routers to which to establish persistent
|
|
connections, as readable from a configuration file, and
|
|
|
|
d. the ability to tell a directory server that (1) it is Blossom-enabled, and
|
|
(2) it can be reached by some set of routers to which it explicitly establishes
|
|
persistent connections.
|
|
|
|
Proposal: Address the aforementioned points as follows.
|
|
|
|
a. need the ability to open a specified number of persistent connections. This
|
|
can be accomplished by implementing a generic should_i_close_this_conn() and
|
|
which_conns_should_i_try_to_open_even_when_i_dont_need_them().
|
|
|
|
b. The Tor design already supports this, but we must be sure to establish the
|
|
persistent connections explicitly, re-establish them when they are lost, and
|
|
not close them unnecessarily.
|
|
|
|
c. We must modify Tor to add a new configuration option, allowing either (a)
|
|
explicit specification of the set of routers to which to establish persistent
|
|
connections, or (b) a random choice of some nodes to which to establish
|
|
persistent connections, chosen from the set of nodes local to the transport
|
|
domain of the specified directory server (for example).
|
|
|
|
III. DIRSERVERS
|
|
|
|
Objective: Blossom directory servers may provide extra
|
|
fields in their network-status pages. Blossom directory servers may
|
|
communicate with Blossom clients/routers in nonstandard ways in addition to
|
|
standard ways.
|
|
|
|
Proposal: Geoff should be able to implement a directory server according to the
|
|
Tor specification (dir-spec.txt).
|
|
|