326 lines
12 KiB
Markdown
326 lines
12 KiB
Markdown
# Testing KiCad #
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[TOC]
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# Unit tests {#unit-tests}
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KiCad has a limited number of unit tests, which can be used to
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check that certain functionality works.
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Tests are registered using [CTest][], part of CMake. CTest gathers all the
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disparate test programs and runs them. Most C++ unit
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tests are written using the [Boost Unit Test framework][], but this is not
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required to add a test to the testing suite.
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The test CMake targets generally start with `qa_`, the names of the tests
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within CTest are the same but without the `qa_` prefix.
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## Running tests {#running-tests}
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You can run all tests after building with `make test` or `ctest`. The latter
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option allows many CTest options which can be useful, especially in automated
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or CI environments.
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### Running specific tests {#running-specific-tests}
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To run a specific test executable, you can just run with `ctest` or run
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the executable directly. Running directly is often the simplest way when
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working on a specific test and you want access to the test executable's
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arguments. For example:
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# run the libcommon tests
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cd /path/to/kicad/build
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qa/common/qa_common [parameters]
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For Boost unit tests, you can see the options for the test with `<test> --help`.
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Common useful patterns:
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* `<test> -t "Utf8/*"` runs all tests in the `Utf8` test suite.
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* `<test> -t "Utf8/UniIterNull"` runs only a single test in a specific suite.
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* `<test> -l all` adds more verbose debugging to the output.
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* `<test> --list_content` lists the test suites and test cases within the
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test program. You can use these for arguments to `-t`.
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You can rebuild just a specific test with CMake to avoid rebuilding
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everything when working on a small area, e.g. `make qa_common`.
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### Automated testing {#automated-testing}
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The unit tests can be run on automated Continuous Integration (CI) systems.
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By default, tests output human-readable results, which is useful when
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developing or debugging, but not so useful for automated test reporting.
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Systems that can parse XML test results can enable these by setting the
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`KICAD_TEST_XML_OUTPUT` option to `ON`. The test results are then output
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as files ending in `.xml` in the `qa` subdirectory.
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Test results are written to the build directory as follows:
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* Boost units tests: one XML file per test with the extension `.boost-results.xml`
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* Python unit tests: one directory per test with the extension `.xunit-results.xml`.
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These directories contain one `.xml` file per Python test case file.
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## Writing Boost tests {#writing-boost-tests}
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Boost unit tests are straightforward to write. Individual test cases can be
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registered with:
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BOOST_AUTO_TEST_CASE( SomeTest )
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{
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BOOST_CHECK_EQUAL( 1, 1 );
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}
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There is a range of functions like `BOOST_CHECK`, which are documented
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[here][boost-test-functions]. Using the most specific function is preferred, as that
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allows Boost to provide more detailed failures: `BOOST_CHECK( foo == bar )` only
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reports a mismatch, `BOOST_CHECK_EQUAL( foo, bar )` will show the values of
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each.
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To output debug messages, you can use `BOOST_TEST_MESSAGE` in the unit tests,
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which will be visible only if you set the `-l` parameter to `message` or higher.
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This colours the text differently to make it stand out from other testing
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messages and standard output.
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You can also use `std::cout`, `printf`, `wxLogDebug` and so on for debug
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messages inside tested functions (i.e. where you don't have access to the Boost
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unit test headers). These will always be printed, so take care
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to remove them before committing, or they'll show up when KiCad runs normally!
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### Expected failures {#expected-failures}
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Sometimes, it is helpful to check in tests that do not pass. However, it is bad
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practise to intentionally check in commits that break builds (which is what
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happens if you cause `make test` to fail).
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Boost provides a method of declaring that some specific tests are allowed to fail.
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This syntax is not consistently available in all supported Boost versions, so you
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should use the following construct:
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```
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#include <unit_test_utils/unit_test_utils.h>
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// On platforms with older boosts, the test will be excluded entirely
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#ifdef HAVE_EXPECTED_FAILURES
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// Declare a test case with 1 "allowed" failure (out of 2, in this case)
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BOOST_AUTO_TEST_CASE( SomeTest, *boost::unit_test::expected_failures( 1 ) )
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{
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BOOST_CHECK_EQUAL( 1, 1 );
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// This check fails, but does not cause a test suite failure
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BOOST_CHECK_EQUAL( 1, 2 );
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// Further failures *would* be a test suit failure
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}
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#endif
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```
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When run, this produces output somewhat like this:
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```
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qa/common/test_mytest.cpp(123): error: in "MyTests/SomeTest": check 1 == 2 has failed [1 != 2
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*** No errors detected
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```
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And the unit test executable returns `0` (success).
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Checking in a failing test is a strictly temporary situation, used to illustrate
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the triggering of a bug prior to fixing it. This is advantageous, not only from
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a "project history" perspective, but also to ensure that the test you write to
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catch the bug in question does, in fact, catch the bug in the first place.
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## Python modules {#python-tests}
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The Pcbnew Python modules have some test programs in the `qa` directory.
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You must have the `KICAD_SCRIPTING_MODULES` option on in CMake to
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build the modules and enable this target.
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The main test script is `qa/test.py` and the test units are in
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`qa/testcases`. All the test units can by run using `ctest python`, which
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runs `test.py`.
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You can also run an individual case manually, by making sure the
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modules are built, adding them to `PYTHONPATH` and running the test
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from the source tree:
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make pcbnew_python_module
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export PYTHONPATH=/path/to/kicad/build/pcbnew
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cd /path/to/kicad/source/qa
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python2 testcase/test_001_pcb_load.py
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### Diagnosing segfaults {#python-segfaults}
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Although the module is Python, it links against a C++ library
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(the same one used by KiCad Pcbnew), so it can segfault if the library
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has a defect.
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You can run the tests in GDB to trace this:
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$ gdb
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(gdb) file python2
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(gdb) run testcases/test_001_pcb_load.py
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If the test segfaults, you will get a familiar backtrace, just like
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if you were running pcbnew under GDB.
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# Utility programs {#utility-programs}
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KiCad includes some utility programs that can be used for debugging, profiling,
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analysing or developing certain parts of the code without having to invoke the full
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GUI program.
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Generally, they are part of the `qa_*_tools` QA executables, each one containing
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the relevant tools for that library. To list the tools in a given program, pass
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the `-l` parameter. Most tools provide help with the `-h` argument.
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To invoke a program:
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qa_<lib>_tools <tool name> [-h] [tool arguments]
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Below is a brief outline of some available tools. For full information and command-line
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parameters, refer to the tools' usage test (`-h`).
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* `common_tools` (the common library and core functions):
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* `coroutine`: A simple coroutine example
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* `io_benchmark`: Show relative speeds of reading files using various IO techniques.
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* `qa_pcbnew_tools` (pcbnew-related functions):
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* `drc`: Run and benchmark certain DRC functions on a user-provided `.kicad_pcb` files
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* `pcb_parser`: Parse user-provided `.kicad_pcb` files
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* `polygon_generator`: Dump polygons found on a PCB to the console
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* `polygon_triangulation`: Perform triangulation of zone polygons on PCBs
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# Fuzz testing {#fuzz-testing}
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It is possible to run fuzz testing on some parts of KiCad. To do this for a
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generic function, you need to be able to pass some kind of input from the fuzz
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testing tool to the function under test.
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For example, to use the [AFL fuzzing tool][], you will need:
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* A test executable that can:
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* Receive input from `stdin` to be run by `afl-fuzz`.
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* Optional: process input from a filename to allow `afl-tmin` to minimise the
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input files.
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* To compile this executable with an AFL compiler, to enable the instrumentation
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that allows the fuzzer to detect the fuzzing state.
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For example, the `qa_pcbnew_tools` executable (which contains `pcb_parser`,
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a fuzz testing tool for `.kicad_pcb` file parsing) can be compiled like this:
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mkdir build
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cd build
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cmake -DCMAKE_CXX_COMPILER=/usr/bin/afl-clang-fast++ -DCMAKE_C_COMPILER=/usr/bin/afl-clang-fast ../kicad_src
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make qa_pcbnew_tools
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You may need to disable core dumps and CPU frequency scaling on your system (AFL
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will warn you if you should do this). For example, as root:
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# echo core >/proc/sys/kernel/core_pattern
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# echo performance | tee cpu*/cpufreq/scaling_governor
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To fuzz, run the executable via `afl-fuzz`:
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afl-fuzz -i fuzzin -o fuzzout -m500 qa/pcbnew_tools/qa_pcbnew_tools pcb_parser
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where:
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* `-i` is a directory of files to use as fuzz input "seeds"
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* `-o` is a directory to write the results (including inputs that provoke crashes
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or hangs)
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* `-t` is the maximum time that a run is allowed to take before being declared a "hang"
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* `-m` is the memory allowed to use (this often needs to be bumped, as KiCad code
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tends to use a lot of memory to initialise)
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The AFL TUI will then display the fuzzing progress, and you can use the hang- or
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crash-provoking inputs to debug code as needed.
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# Run-time debugging {#run-time}
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KiCad can be debugged at run-time, either under a full debugger
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such as GDB, or using simple methods like logging debug to the
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console.
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## Printing debug {#print-debug}
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If you are compiling KiCad yourself, you can simply add debugging statements to
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relevant places in the code, for example:
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wxLogDebug( "Value of variable: %d", my_int );
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This produces debug output that can only be seen when compiling
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in Debug mode.
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You can also use `std::cout` and `printf`.
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Ensure you do not leave this kind of debugging in place when
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submitting code.
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## Printing trace {#trace-debug}
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Some parts of the code have "trace" that can be enabled selectively according to
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a "mask", for example:
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wxLogTrace( "TRACEMASK", "My trace, value: %d", my_int );
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This will not be printed by default. To show it, set the `WXTRACE` environment
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variable when you run KiCad to include the masks you wish to enable:
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$ WXTRACE="TRACEMASK,OTHERMASK" kicad
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When printed, the debug will be prefixed with a timestamp and the trace mask:
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11:22:33: Trace: (TRACEMASK) My trace, value: 42
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If you add a trace mask, define and document the mask as a variable in
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`include/trace_helpers.h`. This will add it to the [trace mask documentation][].
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Some available masks:
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* Core KiCad functions:
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* `KICAD_KEY_EVENTS`
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* `KicadScrollSettings`
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* `KICAD_FIND_ITEM`
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* `KICAD_FIND_REPLACE`
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* `KICAD_NGSPICE`
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* `KICAD_PLUGINLOADER`
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* `GAL_PROFILE`
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* `GAL_CACHED_CONTAINER`
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* `PNS`
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* `CN`
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* `SCROLL_ZOOM` - for the scroll-wheel zooming logic in GAL
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* Plugin-specific (including "standard" KiCad formats):
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* `3D_CACHE`
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* `3D_SG`
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* `3D_RESOLVER`
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* `3D_PLUGIN_MANAGER`
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* `KI_TRACE_CCAMERA`
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* `PLUGIN_IDF`
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* `PLUGIN_VRML`
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* `KICAD_SCH_LEGACY_PLUGIN`
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* `KICAD_GEDA_PLUGIN`
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* `KICAD_PCB_PLUGIN`
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# Advanced configuration {#advanced-configuration}
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There are some advance configuration options, which are mostly used for
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development or testing purposes.
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To set these options, you can create the file `kicad_advanced` and set the keys
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as desired (the [advanced config documentation][] for a current list. You should
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never need to set these keys for normal usage - if you do, that's a bug.
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Any features enabled though the advanced configuration system are
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considered experimental and therefore unsuitable for production use. These
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features are explicitly not supported or considered fully tested.
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Issues are still welcome for defects discovered.
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[CTest]: https://cmake.org/cmake/help/latest/module/CTest.html
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[Boost Unit Test framework]: https://www.boost.org/doc/libs/1_68_0/libs/test/doc/html/index.html
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[boost-test-functions]: https://www.boost.org/doc/libs/1_68_0/libs/test/doc/html/boost_test/utf_reference/testing_tool_ref.html
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[AFL fuzzing tool]: http://lcamtuf.coredump.cx/afl/
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[trace mask documentation]: http://docs.kicad-pcb.org/doxygen/group__trace__env__vars.html
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[trace mask documentation]: http://docs.kicad-pcb.org/doxygen/group__trace__env__vars.html
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[advanced config documentation]: http://docs.kicad-pcb.org/doxygen/namespaceAC__KEYS.html
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