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251 lines
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ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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=============================================
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Open vSwitch datapath developer documentation
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=============================================
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The Open vSwitch kernel module allows flexible userspace control over
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flow-level packet processing on selected network devices. It can be
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used to implement a plain Ethernet switch, network device bonding,
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VLAN processing, network access control, flow-based network control,
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and so on.
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The kernel module implements multiple "datapaths" (analogous to
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bridges), each of which can have multiple "vports" (analogous to ports
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within a bridge). Each datapath also has associated with it a "flow
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table" that userspace populates with "flows" that map from keys based
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on packet headers and metadata to sets of actions. The most common
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action forwards the packet to another vport; other actions are also
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implemented.
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When a packet arrives on a vport, the kernel module processes it by
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extracting its flow key and looking it up in the flow table. If there
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is a matching flow, it executes the associated actions. If there is
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no match, it queues the packet to userspace for processing (as part of
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its processing, userspace will likely set up a flow to handle further
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packets of the same type entirely in-kernel).
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Flow key compatibility
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----------------------
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Network protocols evolve over time. New protocols become important
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and existing protocols lose their prominence. For the Open vSwitch
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kernel module to remain relevant, it must be possible for newer
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versions to parse additional protocols as part of the flow key. It
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might even be desirable, someday, to drop support for parsing
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protocols that have become obsolete. Therefore, the Netlink interface
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to Open vSwitch is designed to allow carefully written userspace
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applications to work with any version of the flow key, past or future.
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To support this forward and backward compatibility, whenever the
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kernel module passes a packet to userspace, it also passes along the
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flow key that it parsed from the packet. Userspace then extracts its
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own notion of a flow key from the packet and compares it against the
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kernel-provided version:
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- If userspace's notion of the flow key for the packet matches the
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kernel's, then nothing special is necessary.
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- If the kernel's flow key includes more fields than the userspace
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version of the flow key, for example if the kernel decoded IPv6
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headers but userspace stopped at the Ethernet type (because it
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does not understand IPv6), then again nothing special is
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necessary. Userspace can still set up a flow in the usual way,
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as long as it uses the kernel-provided flow key to do it.
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- If the userspace flow key includes more fields than the
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kernel's, for example if userspace decoded an IPv6 header but
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the kernel stopped at the Ethernet type, then userspace can
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forward the packet manually, without setting up a flow in the
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kernel. This case is bad for performance because every packet
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that the kernel considers part of the flow must go to userspace,
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but the forwarding behavior is correct. (If userspace can
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determine that the values of the extra fields would not affect
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forwarding behavior, then it could set up a flow anyway.)
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How flow keys evolve over time is important to making this work, so
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the following sections go into detail.
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Flow key format
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---------------
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A flow key is passed over a Netlink socket as a sequence of Netlink
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attributes. Some attributes represent packet metadata, defined as any
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information about a packet that cannot be extracted from the packet
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itself, e.g. the vport on which the packet was received. Most
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attributes, however, are extracted from headers within the packet,
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e.g. source and destination addresses from Ethernet, IP, or TCP
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headers.
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The <linux/openvswitch.h> header file defines the exact format of the
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flow key attributes. For informal explanatory purposes here, we write
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them as comma-separated strings, with parentheses indicating arguments
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and nesting. For example, the following could represent a flow key
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corresponding to a TCP packet that arrived on vport 1::
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in_port(1), eth(src=e0:91:f5:21:d0:b2, dst=00:02:e3:0f:80:a4),
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eth_type(0x0800), ipv4(src=172.16.0.20, dst=172.18.0.52, proto=17, tos=0,
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frag=no), tcp(src=49163, dst=80)
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Often we ellipsize arguments not important to the discussion, e.g.::
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in_port(1), eth(...), eth_type(0x0800), ipv4(...), tcp(...)
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Wildcarded flow key format
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--------------------------
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A wildcarded flow is described with two sequences of Netlink attributes
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passed over the Netlink socket. A flow key, exactly as described above, and an
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optional corresponding flow mask.
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A wildcarded flow can represent a group of exact match flows. Each '1' bit
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in the mask specifies a exact match with the corresponding bit in the flow key.
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A '0' bit specifies a don't care bit, which will match either a '1' or '0' bit
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of a incoming packet. Using wildcarded flow can improve the flow set up rate
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by reduce the number of new flows need to be processed by the user space program.
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Support for the mask Netlink attribute is optional for both the kernel and user
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space program. The kernel can ignore the mask attribute, installing an exact
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match flow, or reduce the number of don't care bits in the kernel to less than
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what was specified by the user space program. In this case, variations in bits
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that the kernel does not implement will simply result in additional flow setups.
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The kernel module will also work with user space programs that neither support
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nor supply flow mask attributes.
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Since the kernel may ignore or modify wildcard bits, it can be difficult for
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the userspace program to know exactly what matches are installed. There are
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two possible approaches: reactively install flows as they miss the kernel
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flow table (and therefore not attempt to determine wildcard changes at all)
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or use the kernel's response messages to determine the installed wildcards.
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When interacting with userspace, the kernel should maintain the match portion
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of the key exactly as originally installed. This will provides a handle to
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identify the flow for all future operations. However, when reporting the
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mask of an installed flow, the mask should include any restrictions imposed
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by the kernel.
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The behavior when using overlapping wildcarded flows is undefined. It is the
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responsibility of the user space program to ensure that any incoming packet
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can match at most one flow, wildcarded or not. The current implementation
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performs best-effort detection of overlapping wildcarded flows and may reject
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some but not all of them. However, this behavior may change in future versions.
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Unique flow identifiers
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-----------------------
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An alternative to using the original match portion of a key as the handle for
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flow identification is a unique flow identifier, or "UFID". UFIDs are optional
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for both the kernel and user space program.
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User space programs that support UFID are expected to provide it during flow
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setup in addition to the flow, then refer to the flow using the UFID for all
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future operations. The kernel is not required to index flows by the original
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flow key if a UFID is specified.
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Basic rule for evolving flow keys
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---------------------------------
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Some care is needed to really maintain forward and backward
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compatibility for applications that follow the rules listed under
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"Flow key compatibility" above.
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The basic rule is obvious::
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==================================================================
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New network protocol support must only supplement existing flow
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key attributes. It must not change the meaning of already defined
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flow key attributes.
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==================================================================
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This rule does have less-obvious consequences so it is worth working
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through a few examples. Suppose, for example, that the kernel module
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did not already implement VLAN parsing. Instead, it just interpreted
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the 802.1Q TPID (0x8100) as the Ethertype then stopped parsing the
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packet. The flow key for any packet with an 802.1Q header would look
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essentially like this, ignoring metadata::
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eth(...), eth_type(0x8100)
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Naively, to add VLAN support, it makes sense to add a new "vlan" flow
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key attribute to contain the VLAN tag, then continue to decode the
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encapsulated headers beyond the VLAN tag using the existing field
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definitions. With this change, a TCP packet in VLAN 10 would have a
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flow key much like this::
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eth(...), vlan(vid=10, pcp=0), eth_type(0x0800), ip(proto=6, ...), tcp(...)
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But this change would negatively affect a userspace application that
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has not been updated to understand the new "vlan" flow key attribute.
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The application could, following the flow compatibility rules above,
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ignore the "vlan" attribute that it does not understand and therefore
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assume that the flow contained IP packets. This is a bad assumption
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(the flow only contains IP packets if one parses and skips over the
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802.1Q header) and it could cause the application's behavior to change
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across kernel versions even though it follows the compatibility rules.
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The solution is to use a set of nested attributes. This is, for
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example, why 802.1Q support uses nested attributes. A TCP packet in
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VLAN 10 is actually expressed as::
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eth(...), eth_type(0x8100), vlan(vid=10, pcp=0), encap(eth_type(0x0800),
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ip(proto=6, ...), tcp(...)))
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Notice how the "eth_type", "ip", and "tcp" flow key attributes are
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nested inside the "encap" attribute. Thus, an application that does
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not understand the "vlan" key will not see either of those attributes
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and therefore will not misinterpret them. (Also, the outer eth_type
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is still 0x8100, not changed to 0x0800.)
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Handling malformed packets
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--------------------------
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Don't drop packets in the kernel for malformed protocol headers, bad
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checksums, etc. This would prevent userspace from implementing a
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simple Ethernet switch that forwards every packet.
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Instead, in such a case, include an attribute with "empty" content.
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It doesn't matter if the empty content could be valid protocol values,
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as long as those values are rarely seen in practice, because userspace
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can always forward all packets with those values to userspace and
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handle them individually.
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For example, consider a packet that contains an IP header that
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indicates protocol 6 for TCP, but which is truncated just after the IP
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header, so that the TCP header is missing. The flow key for this
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packet would include a tcp attribute with all-zero src and dst, like
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this::
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eth(...), eth_type(0x0800), ip(proto=6, ...), tcp(src=0, dst=0)
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As another example, consider a packet with an Ethernet type of 0x8100,
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indicating that a VLAN TCI should follow, but which is truncated just
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after the Ethernet type. The flow key for this packet would include
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an all-zero-bits vlan and an empty encap attribute, like this::
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eth(...), eth_type(0x8100), vlan(0), encap()
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Unlike a TCP packet with source and destination ports 0, an
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all-zero-bits VLAN TCI is not that rare, so the CFI bit (aka
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VLAN_TAG_PRESENT inside the kernel) is ordinarily set in a vlan
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attribute expressly to allow this situation to be distinguished.
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Thus, the flow key in this second example unambiguously indicates a
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missing or malformed VLAN TCI.
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Other rules
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-----------
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The other rules for flow keys are much less subtle:
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- Duplicate attributes are not allowed at a given nesting level.
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- Ordering of attributes is not significant.
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- When the kernel sends a given flow key to userspace, it always
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composes it the same way. This allows userspace to hash and
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compare entire flow keys that it may not be able to fully
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interpret.
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