This folder contains documentation for the P4_16 prototype compiler. The code and documentation are hosted in the following repository: https://github.com/p4lang/p4c
p4c
├── build -- recommended place to build binary
├── backends
│ ├── p4test -- "fake" back-end for testing
│ ├── ebpf -- extended Berkeley Packet Filters back-end
│ ├── graphs -- backend that can draw graphiz graphs of P4 programs
│ └── bmv2 -- behavioral model version 2 (switch simulator) back-end
├── control-plane -- control plane API
├── docs -- documentation
│ └── doxygen -- documentation generation support
├── extensions
│ └── XXXX -- symlinks to custom back-ends
├── frontends
│ ├── common -- common front-end code
│ ├── parsers -- parser and lexer code for P4_14 and P4_16
│ ├── p4-14 -- P4_14 front-end
│ └── p4 -- P4_16 front-end
├── ir -- core internal representation
├── lib -- common utilities (libp4toolkit.a)
├── midend -- code that may be useful for writing mid-ends
├── p4include -- standard P4 files needed by the compiler (e.g., core.p4)
├── test -- test code
│ └── gtest -- unit test code written using gtest
├── tools -- external programs used in the build/test process
│ ├── driver -- p4c compiler driver: a script that invokes various compilers
│ ├── stf -- Python code to parse STF files (used for testing P4 programs)
| └── ir-generator -- code for the IR C++ class hierarchy generator
└── testdata -- test inputs and reference outputs
├── p4_16_samples -- P4_16 input test programs
├── p4_16_errors -- P4_16 negative input test programs
├── p4_16_samples_outputs -- Expected outputs from P4_16 tests
├── p4_16_errors_outputs -- Expected outputs from P4_16 negative tests
├── p4_16_bmv_errors -- P4_16 negative input tests for the bmv2 backend
├── v1_1_samples -- P4 v1.1 sample programs
├── p4_14_errors -- P4_14 negative input test programs
├── p4_14_errors_outputs -- Expected outputs from P4_14 negative tests
├── p4_14_samples -- P4_14 input test programs
├── p4_14_samples_outputs -- Expected outputs from P4_14 tests
└── p4_14_errors -- P4_14 negative input test programs
-
the P4_14 and P4_16 languages are described in their respective specifications, available here.
-
the core design of the compiler intermediate representation (IR) and the visitor patterns are briefly described in IR
-
The migration guide describes how P4_14 (v1.0) programs are translated into P4_16 programs
-
The compiler design describes the salient features of the compiler design and implementation; this document has several subsections:
- Compiler goals
- Compiler architecture
- Source code organization
- IR and visitors; recipes
- A guide to the existing passes
- Discussion of the three sample back-ends
-
Specific back-ends may have their own documentation; check the
extensions
sub-folders, and also the following supplied back-ends: -
Check out the IntelliJ P4 plugin
- do write unit test code
- code has to be reviewed before it is merged
- make sure all tests pass when you send a pull request
- make sure
make cpplint
produces no errors (make check
will also run this) - write documentation
Documenting the workings of the compiler is a never-ending (many times overlooked) job. We can always write better documentation!
In P4C, documentation is generated using Doxygen (http://www.stack.nl/~dimitri/doxygen/index.html). There are two main sources from which we generate documentation: comments in the code and markup documents in the docs/doxygen directory.
Code comments should capture the main intent of the implementation and the "why", rather than the "how". The how can be read from the code, however, documenting the reasons why a certain implementation was chosen will help other contributors understand the design choices and enable them to reuse your code. Also important in the context of the compiler is to document the invariants for each pass (or groups of passes), since it is likely that other developers will need to insert additional passes, and they should understand the effects that the pass ordering has on the AST.
Documentation in the markup documents is intended for higher level design documentation. The files will be automatically captured in the documentation in the order implied by their naming: XX_my_doc.md where XX is a number between 02-99. Currently, 00_revision_history.md contains the documentation revision history, and 01_overview.md is the overview of the compiler goals and architecture.
Happy writing! Should you have any questions, please don't hesitate to ask.
- To contribute: fork the p4lang/p4c repository on github (see https://help.github.com/articles/fork-a-repo/)
- To merge a forked repository with the latest changes in the source use:
git fetch upstream
git rebase upstream/main
git push -f
-
After committing changes, create a pull request (using the github web UI)
-
Follow these guidelines to write commit messages and open pull requests.
-
To debug the build process you can run
make V=1
-
The top-level
.gdbinit
file has some additional pretty-printers. If you start gdb in this folder (p4c), then it should be automatically used. Otherwise you can run at the gdb promptsource path-to-p4c/.gdbinit
. -
To debug the compiler parser you can set the environment variable
YYDEBUG
to 1 -
The following
IR::Node
methods can be used to print nice representations of compiler data structures:-
void dbprint(std::ostream& out) const
: this method is used when logging information. It should print useful debug information, intended for consumption by compiler writers. -
cstring toString() const
: this method is used when reporting error messages to compiler users. It should only display information that is related to the P4 user program, and never internal compiler data structures.
-
-
Use the LOG* macros for writing debug messages. gdb misbehaves frequently, so log messages are the best way to debug your programs. The number in the function name is the debug verbosity. The higher, the less important the message. This macro invokes the
dbprint
method on objects that provide it. Here is an example usage:LOG1("Replacing " << id << " with " << newid);
-
Keep the compiler output deterministic; watch for iterators over sets and maps, which may introduce non-deterministic orders. Use our own
ordered_map
andordered_set
if you iterate, to keep iteration order deterministic. -
You can control the logging level per compiler source-file with the
-T
compiler command-line flag. The flag is followed by a list of file patterns and a numeric level after a colon:
. This flag enables all logging messages above the specified level for all compiler source files that match the file pattern.For example, to enable logging in file
node.cpp
above level 1, and in filepass_manager.cpp
above level 2, use the following compiler command-line option:-Tnode:1,pass_manager:2
To execute LOG statements in a header file you must supply the complete name of the header file, e.g.:
-TfunctionsInlining.h:3
.
The testing infrastructure is based on small python and shell scripts.
-
To run tests execute
make check -j3
- There should be no FAIL or XPASS tests.
- XFAIL tests are tolerated only transiently.
-
To run a subset of tests execute
make check-PATTERN
. E.g.,make check-p4
. -
To rerun the tests that failed last time run
make recheck
-
To run a single test case execute
ctest --output-on-failure -R '<test>'
. Example:ctest --output-on-failure -R 'psa-switch-expression-without-default'
-
Add unit tests in
test/gtest
Test programs with file names ending in -bmv2.p4
or -ebpf.p4
may
have an STF (Simple Test Framework) file with file name suffix .stf
associated with them. If the machine on which you are running has a
copy of simple_switch
or the EBPF software switch installed, not
only will those programs be compiled for those targets, but also table
entries optionally specified in the STF file will be installed, and
input packets will be sent to the data plane and output packets
checked against expected packets in the STF file.
When pull requests are created on the p4c Github repository, the
changes are built, and the tests executed via make check
. These
tests are run with a "recently built" version of simple_switch
from
the
p4lang/behavioral-model
repository, but it can be several hours old. If you are working on
p4c features that rely on newly committed changes to simple_switch
you can find out which simple_switch
version these p4c automated
tests are using at the link below:
-
Coding style is guided by the following rules
-
We use several (but not all) of the Google C++ coding style guidelines. We have customized Google's
cpplint.py
tool for our purposes. The tool can be invoked withmake cpplint
. -
watch out for
const
; it is very important. -
use
override
whenever possible (new gcc versions enforce this) -
never use
const_cast
andreinterpret_cast
. -
The C++ code is written to use a garbage-collector
- do not use any smart pointers, just raw pointers
-
Use our implementations and wrappers instead of standard classes:
-
use
cstring
for constant strings. For java programmers,cstring
should be used where you would use java.lang.String, andstd::string
should be used where you would use StringBuilder or StringBuffer. -
use the
BUG()
macro to signal an exception. This macro is guaranteed to throw an exception. -
use
CHECK_NULL()
to validate that pointers are not nullptr -
use
BUG_CHECK()
instead ofassert
, and always supply an informative error message -
use
::error()
and::warning()
for error reporting. See the guidelines for more details. -
use
LOGn()
for log messages -- then
is an integer constant for verbosity level. These can be controlled on a per-source-file basis with the -T option. LOG1 should be used for general messages, so that running with -T*:1 (turning on all LOG1 messages) is not too overwhelming. LOG2 should be used to print information about the results of a module that later passes may need to debug them. Details of what a module or pass is doing and looking at (only of interest when debugging that code) should be at LOG4 or higher. -
use the
vector
andarray
wrappers forstd::vector
andstd::array
(these do bounds checking on all accesses). -
use
ordered_map
andordered_set
when you need to iterate; they provide deterministic iterators
-
p4c is a compiler driver. The goal is to provide a consistent user interface across different p4 backends and work flows. The compiler driver is written in Python. It can be extended for custom backends.
The usage of the driver is as follows:
usage: p4c [-h] [-V] [-v] [-###] [-Xpreprocessor <arg>] [-Xp4c <arg>]
[-Xassembler <arg>] [-Xlinker <arg>] [-b BACKEND] [-E] [-e] [-S]
[-c] [-x {p4-14,p4-16}] [-I SEARCH_PATH] [-o PATH] [--target-help]
[source_file]
positional arguments:
source_file File to compile
optional arguments:
-h, --help show this help message and exit
-V, --version show version and exit
-v verbose
-### print (but do not run) the commands
-Xpreprocessor <arg> Pass <arg> to the preprocessor
-Xp4c <arg> Pass <arg> to the compiler
-Xassembler <arg> Pass <arg> to the assembler
-Xlinker <arg> Pass <arg> to the linker
-b BACKEND specify target backend
-E Only run the preprocessor
-e Skip the preprocessor
-S Only run the preprocess and compilation steps
-c Only run preprocess, compile, and assemble steps
-x {p4-14,p4-16} Treat subsequent input file as having type language.
-I SEARCH_PATH Add directory to include search path
-o PATH Write output to the provided path
--target-help Display target specific command line options.
To extend the driver, user needs to create a configuration file and add it to the p4c_PYTHON
makefile variable.
# In your custom Makefile.am
p4c_PYTHON += p4c.custom.cfg
There is an global variable config
in p4c compiler driver that stores the build steps
for a particular target. By default, the bmv2 and ebpf backends are supported. Each backend
is identified with a triplet: target-arch-vendor. For example, the default bmv2 backend is
identified as bmv2-ss-p4org
. Users may choose to implement different architectures running
on the same target, and they should configure the compilation flow as follows:
config.add_preprocessor_options("bmv2-newarch-p4org", "-E")
config.add_compiler_options("bmv2-newarch-p4org", "{}/{}.o".format(output_dir, source_basename))
config.add_assembler_options("bmv2-newarch-p4org", "{}/{}.asm".format(output_dir, source_basename))
config.add_linker_options("bmv2-newarch-p4org", "{}/{}.json".format(output_dir, source_basename))
config.add_toolchain("bmv2-newarch-p4org", {"preprocessor": "cc", "compiler": "p4c-bm2-newarch", "assembler": "", "linker": ""})
config.add_compilation_steps(["preprocessor", "compiler"])
config.target.append("bmv2-newarch-p4org")
After adding the new configuration file, rerun bootstrap.sh
For testing purpose, p4c will be installed in the build/ directory when executing make
.
User can install p4c
to other system path by running make install