Signed-off-by: Bill Fischofer <bill.fischo...@linaro.org> --- doc/users-guide/users-guide.adoc | 121 +++++++++++++++++++++++++++++++++++++++ 1 file changed, 121 insertions(+)
diff --git a/doc/users-guide/users-guide.adoc b/doc/users-guide/users-guide.adoc index b3c08a1..513f383 100644 --- a/doc/users-guide/users-guide.adoc +++ b/doc/users-guide/users-guide.adoc @@ -768,6 +768,127 @@ NOTE: Both ordered and parallel queues improve throughput over atomic queues due to parallel event processing, but require that the application take steps to ensure context data synchronization if needed. +== Packet Processing +ODP applications are designed to process packets, which are the basic unit of +data of interest in the data plane. To assist in processing packets, ODP +provides a set of APIs that enable applications to examine and manipulate +packet data and metadata. Packets are referenced by an abstract *odp_packet_t* +handle defined by each implementation. + +Packet objects are normally created at ingress when they arrive at a source +*odp_pktio_t* and are received by an application either directly or (more +typically) foa a scheduled receive queue. They MAY be implicitly freed when +they are transmitted to an output *odp_pktio_t* via an associated transmit +queue, or freed directly via the +odp_packet_free()+ API. + +Occasionally an application may originate a packet itself, either _de novo_ or +by deriving it from an existing packet, and APIs are provided to assist in +these cases as well. Application-created packets can be recycled back through +a _loopback interface_ to reparse and reclassify them, or the application can +do its own parsing as desired. + +Various attributes associated with a packet, such as parse results, are +stored as metadata and APIs are provided to permit applications to examing +and/or modify this information. + +=== Packet Structure and Concepts +A _packet_ consists of a sequence of octets conforming to an architectued +format, such as Ethernet, that can be received and transmitted via the ODP +*pktio* abstraction. Packets of a _length_, which is the number of bytes in +the packet. Packet data in ODP is referenced via _offsets_ since these reflect +the logical contents and structure of a packet independent of how particular +ODP implementations store that data. + +These concetps are shown in the following diagram: + +.ODP Packet Structure +image::../images/packet.svg[align="center"] + +Packet data consists of zero or more _headers_ followed by 0 or more bytes of +_payload_, followed by zero or more _trailers_. Shown here are various APIs +that permit applications to examine and navigate various parts of a packet and +to manipulate its structure. + +To support packet manipulation, predefined _headroom_ and _tailroom_ +areas are logically associated with a packet. Packets can be adjusted by +_pulling_ and _pushing_ these areas. Typical packet processing might consist +of stripping headers from a packet via +odp_pull_head()+ calls as part of +receive procesing and then replacing them with new headers via +odp_push_head()+ +calls as the packet is being prepared for transmit. + +=== Packet Segments and Addressing +ODP platforms use various methods and techniques to store and process packets +efficiently. These vary considerably from platform to platofrm, so to ensure +portability across them ODP adopts certain conventions for referencing +packets. + +ODP APIs use a handle of type *odp_packet_t* to refer to packet objects. +Associated with packets are various bits of system metadata that describe the +packet. By referring to the metadata, ODP applications accelerate packet +processin gby minimizing the need to examine packet data. This is because the +metadata is pupolated by parsing and classification functions that are coupled +to ingress processing that occur prior to a packet being presented to the +application via the ODP scheduler. + +When an ODP application needs to examine the contents of a packet, it requests +addressability to it via an API call that makes the packet (or a contiguously +addressable _segment_ of it) available for coherent access by the application. +To ensure portability, ODP applications assume that the underlying +implementation stores packets in _segments_ of implementation-defined +and managed size. These represent the contiguously addressable portaions of a +packet that the application may refer to via normal memory accesses. ODP +provides APIs that allow applications to operate on packet segments in an +efficient and portable manner as needed. By combining these with the metadata +provided by packets, ODP applications can operate in a fully +platform-independent manner while still achieving optimal performance across +the range of platforms that support DOP. + +The use of segments for packet addressing and their relationship to metadata +is shown in this diagram: + +.ODP Packet Segmentation +image::../images/segment.svg[align="center"] + +The packet metadata is set during parsing and identifies the starting offsets +of the various headers in the packet. The packet itself is physically stored +as a sequence of segments that area managed by the ODP implementation. +Segment 0 is the first segment ofthe packet and is where the packet's headroom +and headers typically reside. Depending on the length of the packet, +additional segmnets may be part of the packet and contain the remaining packet +payload and tailroom. The application need not concern itself with segments +except that when the application requires addressability to a packet it +understands that addressability is provided on a per-segment basis. So, for +example, if the application makes a call like +odp_packet_l4_ptr()+ to obtain +addressability to the packet's Layer 4 header, the returned length from that +call is the number of bytes from the start of the Layer 4 header that are +contiguously addressable to the application from the returned pointer address. +This is because the following byte occupies a different segment and may be +stored elsewhere. To obtain access to those bytes, the application simply +requests addressability to that offset and it will be able to address the +packet bytes that occupy the next segment, etc. Note that the returned +length for any packet addressability call is always the lesser of the remaining +packet length or size of its containing segment. So a mapping for segment 2 +in the above figure, for example, would return a length that extends only to +the end of the packet since the remaining bytes are part of the tailroom +reserved for the packet and are not usable by the application until made +avaialble to it by an appropriate API call. + +=== Metadata Processing +As noted, packet metadata is normally set by the parser as part of +classification that occurs during packet receive processing. It is important +to note that this metadata may be changed by the application to reflect +changes in the packet contents and/or structure as part of its processing of +the packet. While changing this metadata may effect some ODP APIs, changing +metadata is designed to _document_ application changes to the packet but +does not in itself _cause_ those changes to be made. For example, if an +application changes the Layer 3 offset by using the +odp_packet_l3_offset_set()+ +API, the subsequent calls to +odp_packet_l3_ptr()+ will reutrn an address +starting from that changed offset, changing an attribute like ++odp_packet_has_udp_set()+ will not, by itself, turn a non-UDP packet into +a valid UDP packet. Applications are expected to exercise appropriate care +when changing packet metadata to ensure that the resulting metadata changes +reflect the actual changed packet structure that the application has made. + == Cryptographic services ODP provides support for cryptographic operations required by various security -- 2.5.0 _______________________________________________ lng-odp mailing list lng-odp@lists.linaro.org https://lists.linaro.org/mailman/listinfo/lng-odp