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413 lines
16 KiB
Plaintext
Filename: 117-ipv6-exits.txt
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Title: IPv6 exits
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Version: $Revision$
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Last-Modified: $Date$
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Author: coderman
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Created: 10-Jul-2007
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Status: Accepted
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Target: 0.2.1.x
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Overview
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Extend Tor for TCP exit via IPv6 transport and DNS resolution of IPv6
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addresses. This proposal does not imply any IPv6 support for OR
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traffic, only exit and name resolution.
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Contents
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0. Motivation
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As the IPv4 address space becomes more scarce there is increasing
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effort to provide Internet services via the IPv6 protocol. Many
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hosts are available at IPv6 endpoints which are currently
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inaccessible for Tor users.
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Extending Tor to support IPv6 exit streams and IPv6 DNS name
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resolution will allow users of the Tor network to access these hosts.
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This capability would be present for those who do not currently have
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IPv6 access, thus increasing the utility of Tor and furthering
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adoption of IPv6.
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1. Design
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1.1. General design overview
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There are three main components to this proposal. The first is a
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method for routers to advertise their ability to exit IPv6 traffic.
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The second is the manner in which routers resolve names to IPv6
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addresses. Last but not least is the method in which clients
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communicate with Tor to resolve and connect to IPv6 endpoints
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anonymously.
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1.2. Router IPv6 exit support
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In order to specify exit policies and IPv6 capability new directives
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in the Tor configuration will be needed. If a router advertises IPv6
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exit policies in its descriptor this will signal the ability to
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provide IPv6 exit. There are a number of additional default deny
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rules associated with this new address space which are detailed in
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the addendum.
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When Tor is started on a host it should check for the presence of a
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global unicast IPv6 address and if present include the default IPv6
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exit policies and any user specified IPv6 exit policies.
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If a user provides IPv6 exit policies but no global unicast IPv6
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address is available Tor should generate a warning and not publish the
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IPv6 policies in the router descriptor.
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It should be noted that IPv4 mapped IPv6 addresses are not valid exit
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destinations. This mechanism is mainly used to interoperate with
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both IPv4 and IPv6 clients on the same socket. Any attempts to use
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an IPv4 mapped IPv6 address, perhaps to circumvent exit policy for
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IPv4, must be refused.
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1.3. DNS name resolution of IPv6 addresses (AAAA records)
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In addition to exit support for IPv6 TCP connections, a method to
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resolve domain names to their respective IPv6 addresses is also
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needed. This is accomplished in the existing DNS system via AAAA
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records. Routers will perform both A and AAAA requests when
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resolving a name so that the client can utilize an IPv6 endpoint when
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available or preferred.
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To avoid potential problems with caching DNS servers that behave
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poorly all NXDOMAIN responses to AAAA requests should be ignored if a
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successful response is received for an A request. This implies that
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both AAAA and A requests will always be performed for each name
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resolution.
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For reverse lookups on IPv6 addresses, like that used for
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RESOLVE_PTR, Tor will perform the necessary PTR requests via
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IP6.ARPA.
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All routers which perform DNS resolution on behalf of clients
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(RELAY_RESOLVE) should perform and respond with both A and AAAA
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resources.
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[NOTE: In a future version, when we extend the behavior of RESOLVE to
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encapsulate more of real DNS, it will make sense to allow more
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flexibility here. -nickm]
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1.4. Client interaction with IPv6 exit capability
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1.4.1. Usability goals
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There are a number of behaviors which Tor can provide when
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interacting with clients that will improve the usability of IPv6 exit
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capability. These behaviors are designed to make it simple for
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clients to express a preference for IPv6 transport and utilize IPv6
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host services.
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1.4.2. SOCKSv5 IPv6 client behavior
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The SOCKS version 5 protocol supports IPv6 connections. When using
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SOCKSv5 with hostnames it is difficult to determine if a client
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wishes to use an IPv4 or IPv6 address to connect to the desired host
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if it resolves to both address types.
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In order to make this more intuitive the SOCKSv5 protocol can be
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supported on a local IPv6 endpoint, [::1] port 9050 for example.
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When a client requests a connection to the desired host via an IPv6
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SOCKS connection Tor will prefer IPv6 addresses when resolving the
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host name and connecting to the host.
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Likewise, RESOLVE and RESOLVE_PTR requests from an IPv6 SOCKS
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connection will return IPv6 addresses when available, and fall back
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to IPv4 addresses if not.
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[NOTE: This means that SocksListenAddress and DNSListenAddress should
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support IPv6 addresses. Perhaps there should also be a general option
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to have listeners that default to 127.0.0.1 and 0.0.0.0 listen
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additionally or instead on ::1 and :: -nickm]
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1.4.3. MAPADDRESS behavior
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The MAPADDRESS capability supports clients that may not be able to
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use the SOCKSv4a or SOCKSv5 hostname support to resolve names via
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Tor. This ability should be extended to IPv6 addresses in SOCKSv5 as
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well.
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When a client requests an address mapping from the wildcard IPv6
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address, [::0], the server will respond with a unique local IPv6
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address on success. It is important to note that there may be two
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mappings for the same name if both an IPv4 and IPv6 address are
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associated with the host. In this case a CONNECT to a mapped IPv6
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address should prefer IPv6 for the connection to the host, if
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available, while CONNECT to a mapped IPv4 address will prefer IPv4.
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It should be noted that IPv6 does not provide the concept of a host
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local subnet, like 127.0.0.0/8 in IPv4. For this reason integration
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of Tor with IPv6 clients should consider a firewall or filter rule to
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drop unique local addresses to or from the network when possible.
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These packets should not be routed, however, keeping them off the
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subnet entirely is worthwhile.
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1.4.3.1. Generating unique local IPv6 addresses
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The usual manner of generating a unique local IPv6 address is to
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select a Global ID part randomly, along with a Subnet ID, and sharing
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this prefix among the communicating parties who each have their own
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distinct Interface ID. In this style a given Tor instance might
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select a random Global and Subnet ID and provide MAPADDRESS
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assignments with a random Interface ID as needed. This has the
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potential to associate unique Global/Subnet identifiers with a given
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Tor instance and may expose attacks against the anonymity of Tor
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users.
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Tor avoid this potential problem entirely MAPADDRESS must always
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generate the Global, Subnet, and Interface IDs randomly for each
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request. It is also highly suggested that explicitly specifying an
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IPv6 source address instead of the wildcard address not be supported
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to ensure that a good random address is used.
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1.4.4. DNSProxy IPv6 client behavior
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A new capability in recent Tor versions is the transparent DNS proxy.
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This feature will need to return both A and AAAA resource records
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when responding to client name resolution requests.
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The transparent DNS proxy should also support reverse lookups for
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IPv6 addresses. It is suggested that any such requests to the
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deprecated IP6.INT domain should be translated to IP6.ARPA instead.
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This translation is not likely to be used and is of low priority.
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It would be nice to support DNS over IPv6 transport as well, however,
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this is not likely to be used and is of low priority.
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1.4.5. TransPort IPv6 client behavior
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Tor also provides transparent TCP proxy support via the Trans*
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directives in the configuration. The TransListenAddress directive
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should accept an IPv6 address in addition to IPv4 so that IPv6 TCP
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connections can be transparently proxied.
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1.5. Additional changes
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The RedirectExit option should be deprecated rather than extending
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this feature to IPv6.
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2. Spec changes
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2.1. Tor specification
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In '6.2. Opening streams and transferring data' the following should
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be changed to indicate IPv6 exit capability:
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"No version of Tor currently generates the IPv6 format."
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In '6.4. Remote hostname lookup' the following should be updated to
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reflect use of ip6.arpa in addition to in-addr.arpa.
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"For a reverse lookup, the OP sends a RELAY_RESOLVE cell containing an
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in-addr.arpa address."
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In 'A.1. Differences between spec and implementation' the following
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should be updated to indicate IPv6 exit capability:
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"The current codebase has no IPv6 support at all."
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[NOTE: the EXITPOLICY end-cell reason says that it can hold an ipv4 or an
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ipv6 address, but doesn't say how. We may want a separate EXITPOLICY2
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type that can hold an ipv6 address, since the way we encode ipv6
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addresses elsewhere ("0.0.0.0 indicates that the next 16 bytes are ipv6")
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is a bit dumb. -nickm]
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[Actually, the length field lets us distinguish EXITPOLICY. -nickm]
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2.2. Directory specification
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In '2.1. Router descriptor format' a new set of directives is needed
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for IPv6 exit policy. The existing accept/reject directives should
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be clarified to indicate IPv4 or wildcard address relevance. The new
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IPv6 directives will be in the form of:
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"accept6" exitpattern NL
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"reject6" exitpattern NL
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The section describing accept6/reject6 should explain that the
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presence of accept6 or reject6 exit policies in a router descriptor
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signals the ability of that router to exit IPv6 traffic (according to
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IPv6 exit policies).
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The "[::]/0" notation is used to represent "all IPv6 addresses".
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"[::0]/0" may also be used for this representation.
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If a user specifies a 'reject6 [::]/0:*' policy in the Tor
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configuration this will be interpreted as forcing no IPv6 exit
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support and no accept6/reject6 policies will be included in the
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published descriptor. This will prevent IPv6 exit if the router host
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has a global unicast IPv6 address present.
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It is important to note that a wildcard address in an accept or
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reject policy applies to both IPv4 and IPv6 addresses.
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2.3. Control specification
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In '3.8. MAPADDRESS' the potential to have to addresses for a given
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name should be explained. The method for generating unique local
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addresses for IPv6 mappings needs explanation as described above.
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When IPv6 addresses are used in this document they should include the
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brackets for consistency. For example, the null IPv6 address should
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be written as "[::0]" and not "::0". The control commands will
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expect the same syntax as well.
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In '3.9. GETINFO' the "address" command should return both public
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IPv4 and IPv6 addresses if present. These addresses should be
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separated via \r\n.
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2.4. Tor SOCKS extensions
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In '2. Name lookup' a description of IPv6 address resolution is
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needed for SOCKSv5 as described above. IPv6 addresses should be
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supported in both the RESOLVE and RESOLVE_PTR extensions.
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A new section describing the ability to accept SOCKSv5 clients on a
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local IPv6 address to indicate a preference for IPv6 transport as
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described above is also needed. The behavior of Tor SOCKSv5 proxy
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with an IPv6 preference should be explained, for example, preferring
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IPv6 transport to a named host with both IPv4 and IPv6 addresses
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available (A and AAAA records).
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3. Questions and concerns
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3.1. DNS A6 records
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A6 is explicitly avoided in this document. There are potential
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reasons for implementing this, however, the inherent complexity of
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the protocol and resolvers make this unappealing. Is there a
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compelling reason to consider A6 as part of IPv6 exit support?
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[IMO not till anybody needs it. -nickm]
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3.2. IPv4 and IPv6 preference
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The design above tries to infer a preference for IPv4 or IPv6
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transport based on client interactions with Tor. It might be useful
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to provide more explicit control over this preference. For example,
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an IPv4 SOCKSv5 client may want to use IPv6 transport to named hosts
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in CONNECT requests while the current implementation would assume an
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IPv4 preference. Should more explicit control be available, through
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either configuration directives or control commands?
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Many applications support a inet6-only or prefer-family type option
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that provides the user manual control over address preference. This
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could be provided as a Tor configuration option.
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An explicit preference is still possible by resolving names and then
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CONNECTing to an IPv4 or IPv6 address as desired, however, not all
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client applications may have this option available.
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3.3. Support for IPv6 only transparent proxy clients
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It may be useful to support IPv6 only transparent proxy clients using
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IPv4 mapped IPv6 like addresses. This would require transparent DNS
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proxy using IPv6 transport and the ability to map A record responses
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into IPv4 mapped IPv6 like addresses in the manner described in the
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"NAT-PT" RFC for a traditional Basic-NAT-PT with DNS-ALG. The
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transparent TCP proxy would thus need to detect these mapped addresses
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and connect to the desired IPv4 host.
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The IPv6 prefix used for this purpose must not be the actual IPv4
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mapped IPv6 address prefix, though the manner in which IPv4 addresses
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are embedded in IPv6 addresses would be the same.
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The lack of any IPv6 only hosts which would use this transparent proxy
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method makes this a lot of work for very little gain. Is there a
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compelling reason to support this NAT-PT like capability?
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3.4. IPv6 DNS and older Tor routers
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It is expected that many routers will continue to run with older
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versions of Tor when the IPv6 exit capability is released. Clients
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who wish to use IPv6 will need to route RELAY_RESOLVE requests to the
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newer routers which will respond with both A and AAAA resource
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records when possible.
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One way to do this is to route RELAY_RESOLVE requests to routers with
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IPv6 exit policies published, however, this would not utilize current
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routers that can resolve IPv6 addresses even if they can't exit such
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traffic.
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There was also concern expressed about the ability of existing clients
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to cope with new RELAY_RESOLVE responses that contain IPv6 addresses.
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If this breaks backward compatibility, a new request type may be
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necessary, like RELAY_RESOLVE6, or some other mechanism of indicating
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the ability to parse IPv6 responses when making the request.
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3.5. IPv4 and IPv6 bindings in MAPADDRESS
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It may be troublesome to try and support two distinct address mappings
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for the same name in the existing MAPADDRESS implementation. If this
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cannot be accommodated then the behavior should replace existing
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mappings with the new address regardless of family. A warning when
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this occurs would be useful to assist clients who encounter problems
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when both an IPv4 and IPv6 application are using MAPADDRESS for the
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same names concurrently, causing lost connections for one of them.
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4. Addendum
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4.1. Sample IPv6 default exit policy
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reject 0.0.0.0/8
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reject 169.254.0.0/16
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reject 127.0.0.0/8
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reject 192.168.0.0/16
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reject 10.0.0.0/8
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reject 172.16.0.0/12
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reject6 [0000::]/8
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reject6 [0100::]/8
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reject6 [0200::]/7
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reject6 [0400::]/6
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reject6 [0800::]/5
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reject6 [1000::]/4
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reject6 [4000::]/3
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reject6 [6000::]/3
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reject6 [8000::]/3
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reject6 [A000::]/3
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reject6 [C000::]/3
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reject6 [E000::]/4
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reject6 [F000::]/5
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reject6 [F800::]/6
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reject6 [FC00::]/7
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reject6 [FE00::]/9
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reject6 [FE80::]/10
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reject6 [FEC0::]/10
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reject6 [FF00::]/8
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reject *:25
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reject *:119
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reject *:135-139
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reject *:445
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reject *:1214
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reject *:4661-4666
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reject *:6346-6429
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reject *:6699
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reject *:6881-6999
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accept *:*
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# accept6 [2000::]/3:* is implied
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4.2. Additional resources
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'DNS Extensions to Support IP Version 6'
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http://www.ietf.org/rfc/rfc3596.txt
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'DNS Extensions to Support IPv6 Address Aggregation and Renumbering'
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http://www.ietf.org/rfc/rfc2874.txt
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'SOCKS Protocol Version 5'
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http://www.ietf.org/rfc/rfc1928.txt
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'Unique Local IPv6 Unicast Addresses'
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http://www.ietf.org/rfc/rfc4193.txt
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'INTERNET PROTOCOL VERSION 6 ADDRESS SPACE'
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http://www.iana.org/assignments/ipv6-address-space
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'Network Address Translation - Protocol Translation (NAT-PT)'
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http://www.ietf.org/rfc/rfc2766.txt
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