doc: describe the SWX pipeline type
Add the new SWX pipeline type to the Programmer's Guide. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
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Cristian Dumitrescu
David Marchand
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@ -1148,3 +1148,80 @@ Usually, to support a specific functional block, specific implementation of Pack
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with all the implementations sharing the same API: pure SW implementation (no acceleration), implementation using accelerator A, implementation using accelerator B, etc.
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The selection between these implementations could be done at build time or at run-time (recommended), based on which accelerators are present in the system,
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with no application changes required.
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The Software Switch (SWX) Pipeline
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----------------------------------
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The Software Switch (SWX) pipeline is designed to combine the DPDK performance with the flexibility of the P4-16 language [1]. It can be used either by itself
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to code a complete software switch or data plane application, or in combination with the open-source P4 compiler P4C [2], acting as a P4C back-end that allows
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the P4 programs to be translated to the DPDK SWX API and run on multi-core CPUs.
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The main features of the SWX pipeline are:
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* Nothing is hard-wired, everything is dynamically defined: The packet headers (i.e. the network protocols), the packet meta-data, the actions, the tables
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and the pipeline itself are dynamically defined instead of selected from a predefined set.
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* Instructions: The actions and the life of the packet through the pipeline are defined with instructions that manipulate the pipeline objects mentioned
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above. The pipeline is the main function of the packet program, with actions as subroutines triggered by the tables.
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* Call external plugins: Extern objects and functions can be defined to call functionality that cannot be efficiently implemented with the existing
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pipeline-oriented instruction set, such as: error detecting/correcting codes, cryptographic operations, meters, statistics counter arrays, heuristics, etc.
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* Better control plane interaction: Transaction-oriented table update mechanism that supports multi-table atomic updates. Multiple tables can be updated in a
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single step with only the before-update and the after-update table entries visible to the packets. Alignment with the P4Runtime [3] protocol.
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* Performance: Multiple packets are in-flight within the pipeline at any moment. Each packet is owned by a different time-sharing thread in
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run-to-completion, with the thread pausing before memory access operations such as packet I/O and table lookup to allow the memory prefetch to complete.
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The instructions are verified and translated at initialization time with no run-time impact. The instructions are also optimized to detect and "fuse"
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frequently used patterns into vector-like instructions transparently to the user.
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The main SWX pipeline components are:
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* Input and output ports: Each port instantiates a port type that defines the port operations, e.g. Ethernet device port, PCAP port, etc. The RX interface
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of the input ports and the TX interface of the output ports are single packet based, with packet batching typically implemented internally by each port for
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performance reasons.
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* Structure types: Each structure type is used to define the logical layout of a memory block, such as: packet headers, packet meta-data, action data stored
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in a table entry, mailboxes of extern objects and functions. Similar to C language structs, each structure type is a well defined sequence of fields, with
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each field having a unique name and a constant size.
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* Packet headers: Each packet typically has one or multiple headers. The headers are extracted from the input packet as part of the packet parsing operation,
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which is likely executed immediately after the packet reception. As result of the extract operation, each header is logically removed from the packet, so
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once the packet parsing operation is completed, the input packet is reduced to opaque payload. Just before transmission, one or several headers are pushed
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in front of each output packet through the emit operation; these headers can be part of the set of headers that were previously extracted from the input
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packet (and potentially modified afterwards) or some new headers whose contents is generated by the pipeline (e.g. by reading them from tables). The format
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of each packet header is defined by instantiating a structure type.
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* Packet meta-data: The packet meta-data is filled in by the pipeline (e.g. by reading it from tables) or computed by the pipeline. It is not sent out unless
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some of the meta-data fields are explicitly written into the headers emitted into the output packet. The format of the packet meta-data is defined by
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instantiating a structure type.
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* Extern objects and functions: Used to plug into the pipeline any functionality that cannot be efficiently implemented with the existing pipeline instruction
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set. Each extern object and extern function has its own mailbox, which is used to pass the input arguments to and retrieve the output arguments from the
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extern object member functions or the extern function. The mailbox format is defined by instantiating a structure type.
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* Instructions: The pipeline and its actions are defined with instructions from a predefined instruction set. The instructions are used to receive and
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transmit the current packet, extract and emit headers from/into the packet, read/write the packet headers, packet meta-data and mailboxes, start table
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lookup operations, read the action arguments from the table entry, call extern object member functions or extern functions. See the rte_swx_pipeline.h file
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for the complete list of instructions.
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* Actions: The pipeline actions are dynamically defined through instructions as opposed to predefined. Essentially, the actions are subroutines of the
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pipeline program and their execution is triggered by the table lookup. The input arguments of each action are read from the table entry (in case of table
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lookup hit) or the default table action (in case of table lookup miss) and are read-only; their format is defined by instantiating a structure type. The
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actions have read-write access to the packet headers and meta-data.
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* Table: Each pipeline typically has one or more lookup tables. The match fields of each table are flexibly selected from the packet headers and meta-data
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defined for the current pipeline. The set of table actions is flexibly selected for each table from the set of actions defined for the current pipeline. The
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tables can be looked at as special pipeline operators that result in one of the table actions being called, depending on the result of the table lookup
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operation.
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* Pipeline: The pipeline represents the main program that defines the life of the packet, with subroutines (actions) executed on table lookup. As packets
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go through the pipeline, the packet headers and meta-data are transformed along the way.
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References:
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[1] P4-16 specification: https://p4.org/specs/
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[2] P4-16 compiler: https://github.com/p4lang/p4c
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[3] P4Runtime specification: https://p4.org/specs/
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