This project generates packet parsers for use in network devices such as switches and routers. It generates bot fixed and programmable parsers. Fixed parsers use a parse graph that is chosen at generation time, while programmable parsers use a parse graph that is chosen at run time.

The generator was originally created to fascilitate exploration of the parser design space. More information can be found in Design Principles for Packet Parsers by Glen Gibb et al. (See references.)

The generator is not the same version used to produce results for the paper. This version offers fewer configurable parameters in order to make the code easier to understand and modify.

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+-- bin         - scripts used during generation
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+-- build       - target directory for generated files
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+-- examples    - example parse graphs
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+-- lib         - libraries used by the various scripts
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|   +-- Perl5   - Perl libraries
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+-- setup       - environment configuration
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+-- src         - Genesis source files
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    +-- rtl     - RTL for the parser
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    +-- verif   - testbench and associated files

The parser generator uses the Genesis chip generator to perform generation. Information about obtaining Genesis can be found here: http://genesis2.stanford.edu/

The generator produces synthesizable SystemVerilog. Simulation, synthesis, and place-and-route require the use of third party tools. The tools used for testing during development were:

• Synopsys VCS Simulator
• Synopsys Design Compiler
• Synopsys IC Compiler The generated code should work with any tool that supports SystemVerilog.

A parse graph is required to use the parser generator. The logic in a fixed parser is generated specifically for the chosen parse graph. The logic in a programmable parser is independent of the parse graph; however, the parse graph is used to build the test bench and to populate the parse state table (emulated TCAM/RAM) module.

A parse graph is a directed acyclic graph that specifies the types and permitted orderings of headers within a network. The parser identifies a path within the parse graph for each received packet.

Parse graphs are described via text files that list a set of properties for each header. Example parse graphs are found in the examples directory. See README.parse-graphs.md for a description of the format.

The Makefile must be able to execute Genesis and the simulator/synthesis tools. The script in the setup directory provides an example of a bash configuration to set paths appropriately. Customize this to your needs. build/Makefile must be customized for the simulator and synthesis tools you use.

Parsers are generated in the build directory. To build a parser, do:

cd build
make <TARGETS> <PARSER_PARAMS> <VERIF_PARAMS>

Valid targets are:

• clean - clean the build directory of generated files.
• gen - generate a new parser. Synthesizable SystemVerilog is placed in genesis_synth and the test code is place in genesis_verif.
• comp - compile the generated design with the simulator.
• run - run the compiled simulation.
• sim - combination of gen, run, and sim.

PARSER_PARAMS allows parser parameters to be specified to the generator. Parser parameters are specified as:

param1=val1 param2=val2 .. paramN=valN

Parser parameters are:

• PARSE_GRAPH: the parse graph file to use. (Required.)
• WORD_WIDTH: input width of parser (bytes).
• PROG_PARSER: generate a programmable parser? (0 = fixed, 1 = programmable.)
• EV_WIDTH: width of the packet header vector (bits).

Additional parameters for programmable parsers:

• PROG_LOOKUP_WORDS: number of inputs to the parser state table.
• PROG_LOOKUP_WORD_WIDTH: width of each input to the state table.
• PROG_BUF_WORD_WIDTH: width of internal buffer.
• EV_INPUTS: number of extract vector inputs.
• MAX_RD_AMT: maximum number of bytes to advance in a single cycle.

VERIF_PARAMS determines how the test bench/verification code is generated. Verification parameters are specified as:

VERIF_PARAMS="param1=val1 param2=val2 .. paramN=valN"

Verification parameters are:

• MaxPkts: the maximum number of packets for the testbench to generate.
• RandomPktData: fill the test packets with random data for fields not used to determine the next header type. (1 = use random data, 0 = no random data).
• SeqPktData: fill the test packets with sequential data for fields not used to determine the next header type. (1 = use sequential data, 0 = do not use sequential data).

RandomPktData and SeqPktData cannot both be used at the same time. The sequential option overrides the random option if both are specified.

Note: Generating a parser will overwrite any previously generated parsers.

Generate a fixed parser for the parse graph examples/graph-simple.txt using a word width of 4B:

make gen PARSER_PARAMS="ParseGraph=../examples/graph-simple.txt \
                        WordWidth=4"

Generate a programmable parser for the parse graph examples/graph-enterprise.txt using a word width of 8B:

make gen PARSER_PARAMS="ParseGraph=../examples/graph-enterprise.txt \
                        WordWidth=8 \
                        EnableProgParser=1"

The test bench verifies the parser by sending in a sequence of test packets to test each path in the parse graph (or a subset of paths determined by the MaxPkts verification parameter). The test bench verifies that the correct packet header vector is output for each input file.

• Design Principles for Packet Parsers. Glen Gibb, George Varghese, Mark Horowitz, and Nick McKeown: http://dl.acm.org/citation.cfm?id=2537857.2537860&coll=DL&dl=GUIDE&CFID=222668031&CFTOKEN=52789323
• Reconfigurable Hardware for Software-Defined Networks, Chapter 2. Glen Gibb: http://purl.stanford.edu/ns046rz4288