############ Contributing ############ Help is always appreciated! To get started, you can try :ref:`building-from-source` in order to familiarize yourself with the components of Solidity and the build process. Also, it may be useful to become well-versed at writing smart-contracts in Solidity. In particular, we need help in the following areas: * Improving the documentation * Responding to questions from other users on `StackExchange `_ and the `Solidity Gitter `_ * Fixing and responding to `Solidity's GitHub issues `_, especially those tagged as `up-for-grabs `_ which are meant as introductory issues for external contributors. How to Report Issues ==================== To report an issue, please use the `GitHub issues tracker `_. When reporting issues, please mention the following details: * Which version of Solidity you are using * What was the source code (if applicable) * Which platform are you running on * How to reproduce the issue * What was the result of the issue * What the expected behaviour is Reducing the source code that caused the issue to a bare minimum is always very helpful and sometimes even clarifies a misunderstanding. Workflow for Pull Requests ========================== In order to contribute, please fork off of the ``develop`` branch and make your changes there. Your commit messages should detail *why* you made your change in addition to *what* you did (unless it is a tiny change). If you need to pull in any changes from ``develop`` after making your fork (for example, to resolve potential merge conflicts), please avoid using ``git merge`` and instead, ``git rebase`` your branch. Additionally, if you are writing a new feature, please ensure you write appropriate Boost test cases and place them under ``test/``. However, if you are making a larger change, please consult with the `Solidity Development Gitter channel `_ (different from the one mentioned above, this on is focused on compiler and language development instead of language use) first. New features and bugfixes should be added to the ``Changelog.md`` file: please follow the style of previous entries, when applicable. Finally, please make sure you respect the `coding style `_ for this project. Also, even though we do CI testing, please test your code and ensure that it builds locally before submitting a pull request. Thank you for your help! Running the compiler tests ========================== Solidity includes different types of tests. They are included in the application called ``soltest``. Some of them require the ``cpp-ethereum`` client in testing mode, some others require ``libz3`` to be installed. ``soltest`` reads test contracts that are annotated with expected results stored in ``./test/libsolidity/syntaxTests``. In order for soltest to find these tests the root test directory has to be specified using the ``--testpath`` command line option, e.g. ``./build/test/soltest -- --testpath ./test``. To disable the z3 tests, use ``./build/test/soltest -- --no-smt --testpath ./test`` and to run a subset of the tests that do not require ``cpp-ethereum``, use ``./build/test/soltest -- --no-ipc --testpath ./test``. For all other tests, you need to install `cpp-ethereum `_ and run it in testing mode: ``eth --test -d /tmp/testeth``. Then you run the actual tests: ``./build/test/soltest -- --ipcpath /tmp/testeth/geth.ipc --testpath ./test``. To run a subset of tests, filters can be used: ``soltest -t TestSuite/TestName -- --ipcpath /tmp/testeth/geth.ipc --testpath ./test``, where ``TestName`` can be a wildcard ``*``. Alternatively, there is a testing script at ``scripts/test.sh`` which executes all tests and runs ``cpp-ethereum`` automatically if it is in the path (but does not download it). Travis CI even runs some additional tests (including ``solc-js`` and testing third party Solidity frameworks) that require compiling the Emscripten target. Writing and running syntax tests -------------------------------- As mentioned above, syntax tests are stored in individual contracts. These files must contain annotations, stating the expected result(s) of the respective test. The test suite will compile and check them against the given expectations. Example: ``./test/libsolidity/syntaxTests/double_stateVariable_declaration.sol`` :: contract test { uint256 variable; uint128 variable; } // ---- // DeclarationError: Identifier already declared. A syntax test must contain at least the contract under test itself, followed by the separator ``----``. The additional comments above are used to describe the expected compiler errors or warnings. This section can be empty in case that the contract should compile without any errors or warnings. In the above example, the state variable ``variable`` was declared twice, which is not allowed. This will result in a ``DeclarationError`` stating that the identifier was already declared. The tool that is being used for those tests is called ``isoltest`` and can be found under ``./test/tools/``. It is an interactive tool which allows editing of failing contracts using your preferred text editor. Let's try to break this test by removing the second declaration of ``variable``: :: contract test { uint256 variable; } // ---- // DeclarationError: Identifier already declared. Running ``./test/isoltest`` again will result in a test failure: :: syntaxTests/double_stateVariable_declaration.sol: FAIL Contract: contract test { uint256 variable; } Expected result: DeclarationError: Identifier already declared. Obtained result: Success which prints the expected result next to the obtained result, but also provides a way to change edit / update / skip the current contract or to even quit. ``isoltest`` offers several options for failing tests: - edit: ``isoltest`` will try to open the editor that was specified before using ``isoltest --editor /path/to/editor``. If no path was set, this will result in a runtime error. In case an editor was specified, this will open it such that the contract can be adjusted. - update: Updates the contract under test. This will either remove the annotation which contains the exception not met or will add missing expectations. The test will then be run again. - skip: Skips the execution of this particular test. - quit: Quits ``isoltest``. Automatically updating the test above will change it to :: contract test { uint256 variable; } // ---- and re-run the test. It will now pass again: :: Re-running test case... syntaxTests/double_stateVariable_declaration.sol: OK .. note:: Please choose a name for the contract file, that is self-explainatory in the sense of what is been tested, e.g. ``double_variable_declaration.sol``. Do not put more than one contract into a single file. ``isoltest`` is currently not able to recognize them individually. Running the Fuzzer via AFL ========================== Fuzzing is a technique that runs programs on more or less random inputs to find exceptional execution states (segmentation faults, exceptions, etc). Modern fuzzers are clever and do a directed search inside the input. We have a specialized binary called ``solfuzzer`` which takes source code as input and fails whenever it encounters an internal compiler error, segmentation fault or similar, but does not fail if e.g. the code contains an error. This way, internal problems in the compiler can be found by fuzzing tools. We mainly use `AFL `_ for fuzzing. You need to download and install AFL packages from your repos (afl, afl-clang) or build them manually. Next, build Solidity (or just the ``solfuzzer`` binary) with AFL as your compiler: :: cd build # if needed make clean cmake .. -DCMAKE_C_COMPILER=path/to/afl-gcc -DCMAKE_CXX_COMPILER=path/to/afl-g++ make solfuzzer At this stage you should be able to see a message similar to the following: :: Scanning dependencies of target solfuzzer [ 98%] Building CXX object test/tools/CMakeFiles/solfuzzer.dir/fuzzer.cpp.o afl-cc 2.52b by afl-as 2.52b by [+] Instrumented 1949 locations (64-bit, non-hardened mode, ratio 100%). [100%] Linking CXX executable solfuzzer If the instrumentation messages did not appear, try switching the cmake flags pointing to AFL's clang binaries: :: # if previously failed make clean cmake .. -DCMAKE_C_COMPILER=path/to/afl-clang -DCMAKE_CXX_COMPILER=path/to/afl-clang++ make solfuzzer Othwerise, upon execution the fuzzer will halt with an error saying binary is not instrumented: :: afl-fuzz 2.52b by ... (truncated messages) [*] Validating target binary... [-] Looks like the target binary is not instrumented! The fuzzer depends on compile-time instrumentation to isolate interesting test cases while mutating the input data. For more information, and for tips on how to instrument binaries, please see /usr/share/doc/afl-doc/docs/README. When source code is not available, you may be able to leverage QEMU mode support. Consult the README for tips on how to enable this. (It is also possible to use afl-fuzz as a traditional, "dumb" fuzzer. For that, you can use the -n option - but expect much worse results.) [-] PROGRAM ABORT : No instrumentation detected Location : check_binary(), afl-fuzz.c:6920 Next, you need some example source files. This will make it much easier for the fuzzer to find errors. You can either copy some files from the syntax tests or extract test files from the documentation or the other tests: :: mkdir /tmp/test_cases cd /tmp/test_cases # extract from tests: path/to/solidity/scripts/isolate_tests.py path/to/solidity/test/libsolidity/SolidityEndToEndTest.cpp # extract from documentation: path/to/solidity/scripts/isolate_tests.py path/to/solidity/docs docs The AFL documentation states that the corpus (the initial input files) should not be too large. The files themselves should not be larger than 1 kB and there should be at most one input file per functionality, so better start with a small number of input files. There is also a tool called ``afl-cmin`` that can trim input files that result in similar behaviour of the binary. Now run the fuzzer (the ``-m`` extends the size of memory to 60 MB): :: afl-fuzz -m 60 -i /tmp/test_cases -o /tmp/fuzzer_reports -- /path/to/solfuzzer The fuzzer will create source files that lead to failures in ``/tmp/fuzzer_reports``. Often it finds many similar source files that produce the same error. You can use the tool ``scripts/uniqueErrors.sh`` to filter out the unique errors. Whiskers ======== *Whiskers* is a templating system similar to `Mustache `_. It is used by the compiler in various places to aid readability, and thus maintainability and verifiability, of the code. The syntax comes with a substantial difference to Mustache: the template markers ``{{`` and ``}}`` are replaced by ``<`` and ``>`` in order to aid parsing and avoid conflicts with :ref:`inline-assembly` (The symbols ``<`` and ``>`` are invalid in inline assembly, while ``{`` and ``}`` are used to delimit blocks). Another limitation is that lists are only resolved one depth and they will not recurse. This may change in the future. A rough specification is the following: Any occurrence of ```` is replaced by the string-value of the supplied variable ``name`` without any escaping and without iterated replacements. An area can be delimited by ``<#name>...``. It is replaced by as many concatenations of its contents as there were sets of variables supplied to the template system, each time replacing any ```` items by their respective value. Top-level variables can also be used inside such areas.