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+.. _srv6_as_plugin_doc:
+
+SRv6 static proxy
+=================
+
+The document describes SRv6 endpoint to SR-unaware appliance via static
+proxy (End.AS)
+
+Overview
+--------
+
+The static proxy is an SR endpoint behavior for processing SR-MPLS or
+SRv6 encapsulated traffic on behalf of an SR-unaware SF. This proxy thus
+receives SR traffic that is formed of an MPLS label stack or an IPv6
+header on top of an inner packet, which can be Ethernet, IPv4 or IPv6.
+
+A static SR proxy segment is associated with the following mandatory
+parameters:
+
+-  INNER-TYPE: Inner packet type
+-  S-ADDR: Ethernet or IP address of the SF (only for inner type IPv4
+   and IPv6)
+-  IFACE-OUT: Local interface for sending traffic towards the SF
+-  IFACE-IN: Local interface receiving the traffic coming back from the
+   SF
+-  CACHE: SR information to be attached on the traffic coming back from
+   the SF, including at least
+
+   -  CACHE.SA: IPv6 source address (SRv6 only)
+   -  CACHE.LIST: Segment list expressed as MPLS labels or IPv6 address
+
+A static SR proxy segment is thus defined for a specific SF, inner
+packet type and cached SR information. It is also bound to a pair of
+directed interfaces on the proxy. These may be both directions of a
+single interface, or opposite directions of two different interfaces.
+The latter is recommended in case the SF is to be used as part of a
+bi-directional SR SC policy. If the proxy and the SF both support
+802.1Q, IFACE-OUT and IFACE-IN can also represent sub-interfaces.
+
+The first part of this behavior is triggered when the proxy node
+receives a packet whose active segment matches a segment associated with
+the static proxy behavior. It removes the SR information from the packet
+then sends it on a specific interface towards the associated SF. This SR
+information corresponds to the full label stack for SR-MPLS or to the
+encapsulation IPv6 header with any attached extension header in the case
+of SRv6.
+
+The second part is an inbound policy attached to the proxy interface
+receiving the traffic returning from the SF, IFACE-IN. This policy
+attaches to the incoming traffic the cached SR information associated
+with the SR proxy segment. If the proxy segment uses the SR-MPLS data
+plane, CACHE contains a stack of labels to be pushed on top the packets.
+With the SRv6 data plane, CACHE is defined as a source address, an
+active segment and an optional SRH (tag, segments left, segment list and
+metadata). The proxy encapsulates the packets with an IPv6 header that
+has the source address, the active segment as destination address and
+the SRH as a routing extension header. After the SR information has been
+attached, the packets are forwarded according to the active segment,
+which is represented by the top MPLS label or the IPv6 Destination
+Address.
+
+In this scenario, there are no restrictions on the operations that can
+be performed by the SF on the stream of packets. It may operate at all
+protocol layers, terminate transport layer connections, generate new
+packets and initiate transport layer connections. This behavior may also
+be used to integrate an IPv4-only SF into an SRv6 policy. However, a
+static SR proxy segment can be used in only one service chain at a time.
+As opposed to most other segment types, a static SR proxy segment is
+bound to a unique list of segments, which represents a directed SR SC
+policy. This is due to the cached SR information being defined in the
+segment configuration. This limitation only prevents multiple segment
+lists from using the same static SR proxy segment at the same time, but
+a single segment list can be shared by any number of traffic flows.
+Besides, since the returning traffic from the SF is re-classified based
+on the incoming interface, an interface can be used as receiving
+interface (IFACE-IN) only for a single SR proxy segment at a time. In
+the case of a bi-directional SR SC policy, a different SR proxy segment
+and receiving interface are required for the return direction.
+
+For more information, please see
+`draft-xuclad-spring-sr-service-chaining <https://datatracker.ietf.org/doc/draft-xuclad-spring-sr-service-chaining/>`__.
+
+CLI configuration
+-----------------
+
+The following command instantiates a new End.AS segment that sends the
+inner packets on interface ``IFACE-OUT`` towards an appliance at address
+``S-ADDR`` and restores the segment list ``<S1, S2, S3>`` with a source
+address ``SRC-ADDR`` on the packets coming back on interface
+``IFACE-IN``.
+
+::
+
+   sr localsid address SID behavior end.as nh S-ADDR oif IFACE-OUT iif IFACE-IN src SRC-ADDR next S1 next S2 next S3
+
+For example, the below command configures the SID ``1::A1`` with an
+End.AS function for sending traffic on interface
+``GigabitEthernet0/8/0`` to the appliance at address ``A1::``, and
+receiving it back on interface ``GigabitEthernet0/9/0``.
+
+::
+
+   sr localsid address 1::A1 behavior end.as nh A1:: oif GigabitEthernet0/8/0 iif GigabitEthernet0/9/0 src 1:: next 2::20 next 3::30 next 4::40
+
+Pseudocode
+----------
+
+Static proxy for inner type IPv4
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Upon receiving an IPv6 packet destined for S, where S is an IPv6 static
+proxy segment for IPv4 traffic, a node N does:
+
+::
+
+   IF ENH == 4 THEN                                                ;; Ref1
+       Remove the (outer) IPv6 header and its extension headers
+       Forward the exposed packet on IFACE-OUT towards S-ADDR
+   ELSE
+       Drop the packet
+
+**Ref1:** 4 refers to IPv4 encapsulation as defined by IANA allocation
+for Internet Protocol Numbers.
+
+Upon receiving a non link-local IPv4 packet on IFACE-IN, a node N does:
+
+::
+
+   Decrement TTL and update checksum
+   IF CACHE.SRH THEN                                               ;; Ref2
+       Push CACHE.SRH on top of the existing IPv4 header
+       Set NH value of the pushed SRH to 4
+   Push outer IPv6 header with SA, DA and traffic class from CACHE
+   Set outer payload length and flow label
+   Set NH value to 43 if an SRH was added, or 4 otherwise
+   Lookup outer DA in appropriate table and proceed accordingly
+
+**Ref2:** CACHE.SRH represents the SRH defined in CACHE, if any, for the
+static SR proxy segment associated with IFACE-IN.
+
+Static proxy for inner type IPv6
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Upon receiving an IPv6 packet destined for S, where S is an IPv6 static
+proxy segment for IPv6 traffic, a node N does:
+
+::
+
+   IF ENH == 41 THEN                                               ;; Ref1
+       Remove the (outer) IPv6 header and its extension headers
+       Forward the exposed packet on IFACE-OUT towards S-ADDR
+   ELSE
+       Drop the packet
+
+**Ref1:** 41 refers to IPv6 encapsulation as defined by IANA allocation
+for Internet Protocol Numbers.
+
+Upon receiving a non-link-local IPv6 packet on IFACE-IN, a node N does:
+
+::
+
+   Decrement Hop Limit
+   IF CACHE.SRH THEN                                               ;; Ref2
+       Push CACHE.SRH on top of the existing IPv6 header
+       Set NH value of the pushed SRH to 41
+   Push outer IPv6 header with SA, DA and traffic class from CACHE
+   Set outer payload length and flow label
+   Set NH value to 43 if an SRH was added, or 41 otherwise
+   Lookup outer DA in appropriate table and proceed accordingly
+
+**Ref2:** CACHE.SRH represents the SRH defined in CACHE, if any, for the
+static SR proxy segment associated with IFACE-IN.