.. include:: replace.txt .. highlight:: bash Testing framework ----------------- |ns3| consists of a simulation core engine, a set of models, example programs, and tests. Over time, new contributors contribute models, tests, and examples. A Python test program ``test.py`` serves as the test execution manager; ``test.py`` can run test code and examples to look for regressions, can output the results into a number of forms, and can manage code coverage analysis tools. On top of this, we layer *buildslaves* that are automated build robots that perform robustness testing by running the test framework on different systems and with different configuration options. Buildslaves *********** At the highest level of |ns3| testing are the buildslaves (build robots). If you are unfamiliar with this system look at ``_. This is an open-source automated system that allows |ns3| to be rebuilt and tested daily. By running the buildbots on a number of different systems we can ensure that |ns3| builds and executes properly on all of its supported systems. Users (and developers) typically will not interact with the buildslave system other than to read its messages regarding test results. If a failure is detected in one of the automated build and test jobs, the buildbot will send an email to the *ns-commits* mailing list. This email will look something like .. sourcecode:: text [Ns-commits] Build failed in Jenkins: daily-ubuntu-without-valgrind ยป Ubuntu-64-15.04 #926 ... 281 of 285 tests passed (281 passed, 3 skipped, 1 failed, 0 crashed, 0 valgrind errors) List of SKIPped tests: ns3-tcp-cwnd ns3-tcp-interoperability nsc-tcp-loss List of FAILed tests: random-variable-stream-generators + exit 1 Build step 'Execute shell' marked build as failure In the full details URL shown in the email, one can find links to the detailed test output. The buildslave system will do its job quietly if there are no errors, and the system will undergo build and test cycles every day to verify that all is well. Test.py ******* The buildbots use a Python program, ``test.py``, that is responsible for running all of the tests and collecting the resulting reports into a human- readable form. This program is also available for use by users and developers as well. ``test.py`` is very flexible in allowing the user to specify the number and kind of tests to run; and also the amount and kind of output to generate. Before running ``test.py``, make sure that ns3's examples and tests have been built by doing the following :: $ ./ns3 configure --enable-examples --enable-tests $ ./ns3 build By default, ``test.py`` will run all available tests and report status back in a very concise form. Running the command :: $ ./test.py will result in a number of ``PASS``, ``FAIL``, ``CRASH`` or ``SKIP`` indications followed by the kind of test that was run and its display name. .. sourcecode:: text Waf: Entering directory `/home/craigdo/repos/ns-3-allinone-test/ns-3-dev/build' Waf: Leaving directory `/home/craigdo/repos/ns-3-allinone-test/ns-3-dev/build' 'build' finished successfully (0.939s) FAIL: TestSuite propagation-loss-model PASS: TestSuite object-name-service PASS: TestSuite pcap-file-object PASS: TestSuite ns3-tcp-cwnd ... PASS: TestSuite ns3-tcp-interoperability PASS: Example csma-broadcast PASS: Example csma-multicast This mode is intended to be used by users who are interested in determining if their distribution is working correctly, and by developers who are interested in determining if changes they have made have caused any regressions. There are a number of options available to control the behavior of ``test.py``. if you run ``test.py --help`` you should see a command summary like: .. sourcecode:: text Usage: test.py [options] Options: -h, --help show this help message and exit -b BUILDPATH, --buildpath=BUILDPATH specify the path where ns-3 was built (defaults to the build directory for the current variant) -c KIND, --constrain=KIND constrain the test-runner by kind of test -e EXAMPLE, --example=EXAMPLE specify a single example to run (no relative path is needed) -d, --duration print the duration of each test suite and example -e EXAMPLE, --example=EXAMPLE specify a single example to run (no relative path is needed) -u, --update-data If examples use reference data files, get them to re- generate them -f FULLNESS, --fullness=FULLNESS choose the duration of tests to run: QUICK, EXTENSIVE, or TAKES_FOREVER, where EXTENSIVE includes QUICK and TAKES_FOREVER includes QUICK and EXTENSIVE (only QUICK tests are run by default) -g, --grind run the test suites and examples using valgrind -k, --kinds print the kinds of tests available -l, --list print the list of known tests -m, --multiple report multiple failures from test suites and test cases -n, --nobuild do not run ns3 before starting testing -p PYEXAMPLE, --pyexample=PYEXAMPLE specify a single python example to run (with relative path) -r, --retain retain all temporary files (which are normally deleted) -s TEST-SUITE, --suite=TEST-SUITE specify a single test suite to run -t TEXT-FILE, --text=TEXT-FILE write detailed test results into TEXT-FILE.txt -v, --verbose print progress and informational messages -w HTML-FILE, --web=HTML-FILE, --html=HTML-FILE write detailed test results into HTML-FILE.html -x XML-FILE, --xml=XML-FILE write detailed test results into XML-FILE.xml If one specifies an optional output style, one can generate detailed descriptions of the tests and status. Available styles are ``text`` and ``HTML``. The buildbots will select the HTML option to generate HTML test reports for the nightly builds using :: $ ./test.py --html=nightly.html In this case, an HTML file named ''nightly.html'' would be created with a pretty summary of the testing done. A ''human readable'' format is available for users interested in the details. :: $ ./test.py --text=results.txt In the example above, the test suite checking the |ns3| wireless device propagation loss models failed. By default no further information is provided. To further explore the failure, ``test.py`` allows a single test suite to be specified. Running the command :: $ ./test.py --suite=propagation-loss-model or equivalently :: $ ./test.py -s propagation-loss-model results in that single test suite being run. .. sourcecode:: text FAIL: TestSuite propagation-loss-model To find detailed information regarding the failure, one must specify the kind of output desired. For example, most people will probably be interested in a text file:: $ ./test.py --suite=propagation-loss-model --text=results.txt This will result in that single test suite being run with the test status written to the file ''results.txt''. You should find something similar to the following in that file .. sourcecode:: text FAIL: Test Suite ''propagation-loss-model'' (real 0.02 user 0.01 system 0.00) PASS: Test Case "Check ... Friis ... model ..." (real 0.01 user 0.00 system 0.00) FAIL: Test Case "Check ... Log Distance ... model" (real 0.01 user 0.01 system 0.00) Details: Message: Got unexpected SNR value Condition: [long description of what actually failed] Actual: 176.395 Limit: 176.407 +- 0.0005 File: ../src/test/ns3wifi/propagation-loss-models-test-suite.cc Line: 360 Notice that the Test Suite is composed of two Test Cases. The first test case checked the Friis propagation loss model and passed. The second test case failed checking the Log Distance propagation model. In this case, an SNR of 176.395 was found, and the test expected a value of 176.407 correct to three decimal places. The file which implemented the failing test is listed as well as the line of code which triggered the failure. If you desire, you could just as easily have written an HTML file using the ``--html`` option as described above. Typically a user will run all tests at least once after downloading |ns3| to ensure that his or her environment has been built correctly and is generating correct results according to the test suites. Developers will typically run the test suites before and after making a change to ensure that they have not introduced a regression with their changes. In this case, developers may not want to run all tests, but only a subset. For example, the developer might only want to run the unit tests periodically while making changes to a repository. In this case, ``test.py`` can be told to constrain the types of tests being run to a particular class of tests. The following command will result in only the unit tests being run:: $ ./test.py --constrain=unit To see a quick list of the legal kinds of constraints, you can ask for them to be listed. The following command :: $ ./test.py --kinds will result in the following list being displayed: .. sourcecode:: text Waf: Entering directory `/home/craigdo/repos/ns-3-allinone-test/ns-3-dev/build' Waf: Leaving directory `/home/craigdo/repos/ns-3-allinone-test/ns-3-dev/build' 'build' finished successfully (0.939s)Waf: Entering directory `/home/craigdo/repos/ns-3-allinone-test/ns-3-dev/build' core: Run all TestSuite-based tests (exclude examples) example: Examples (to see if example programs run successfully) performance: Performance Tests (check to see if the system is as fast as expected) system: System Tests (spans modules to check integration of modules) unit: Unit Tests (within modules to check basic functionality) Any of these kinds of test can be provided as a constraint using the ``--constraint`` option. To see a quick list of all of the test suites available, you can ask for them to be listed. The following command, :: $ ./test.py --list will result in a list of the test suite being displayed, similar to .. sourcecode:: text Waf: Entering directory `/home/craigdo/repos/ns-3-allinone-test/ns-3-dev/build' Waf: Leaving directory `/home/craigdo/repos/ns-3-allinone-test/ns-3-dev/build' 'build' finished successfully (0.939s) Test Type Test Name --------- --------- performance many-uniform-random-variables-one-get-value-call performance one-uniform-random-variable-many-get-value-calls performance type-id-perf system buildings-pathloss-test system buildings-shadowing-test system devices-mesh-dot11s-regression system devices-mesh-flame-regression system epc-gtpu ... unit wimax-phy-layer unit wimax-service-flow unit wimax-ss-mac-layer unit wimax-tlv example adhoc-aloha-ideal-phy example adhoc-aloha-ideal-phy-matrix-propagation-loss-model example adhoc-aloha-ideal-phy-with-microwave-oven example aodv ... Any of these listed suites can be selected to be run by itself using the ``--suite`` option as shown above. To run multiple test suites at once it is possible to use a 'Unix filename pattern matching' style, e.g., :: $ ../test.py -s 'ipv6*' Note the use of quotes. The result is similar to .. sourcecode:: text PASS: TestSuite ipv6-protocol PASS: TestSuite ipv6-packet-info-tag PASS: TestSuite ipv6-list-routing PASS: TestSuite ipv6-extension-header PASS: TestSuite ipv6-address-generator PASS: TestSuite ipv6-raw PASS: TestSuite ipv6-dual-stack PASS: TestSuite ipv6-fragmentation PASS: TestSuite ipv6-address-helper PASS: TestSuite ipv6-address PASS: TestSuite ipv6-forwarding PASS: TestSuite ipv6-ripng Similarly to test suites, one can run a single C++ example program using the ``--example`` option. Note that the relative path for the example does not need to be included and that the executables built for C++ examples do not have extensions. Furthermore, the example must be registered as an example to the test framework; it is not sufficient to create an example and run it through test.py; it must be added to the relevant ``examples-to-run.py`` file, explained below. Entering :: $ ./test.py --example=udp-echo results in that single example being run. .. sourcecode:: text PASS: Example examples/udp/udp-echo You can specify the directory where |ns3| was built using the ``--buildpath`` option as follows. :: $ ./test.py --buildpath=/home/craigdo/repos/ns-3-allinone-test/ns-3-dev/build/debug --example=wifi-simple-adhoc One can run a single Python example program using the ``--pyexample`` option. Note that the relative path for the example must be included and that Python examples do need their extensions. Entering :: $ ./test.py --pyexample=examples/tutorial/first.py results in that single example being run. .. sourcecode:: text PASS: Example examples/tutorial/first.py Because Python examples are not built, you do not need to specify the directory where |ns3| was built to run them. Normally when example programs are executed, they write a large amount of trace file data. This is normally saved to the base directory of the distribution (e.g., /home/user/ns-3-dev). When ``test.py`` runs an example, it really is completely unconcerned with the trace files. It just wants to to determine if the example can be built and run without error. Since this is the case, the trace files are written into a ``/tmp/unchecked-traces`` directory. If you run the above example, you should be able to find the associated ``udp-echo.tr`` and ``udp-echo-n-1.pcap`` files there. The list of available examples is defined by the contents of the ''examples'' directory in the distribution. If you select an example for execution using the ``--example`` option, ``test.py`` will not make any attempt to decide if the example has been configured or not, it will just try to run it and report the result of the attempt. When ``test.py`` runs, by default it will first ensure that the system has been completely built. This can be defeated by selecting the ``--nobuild`` option. :: $ ./test.py --list --nobuild will result in a list of the currently built test suites being displayed, similar to: .. sourcecode:: text propagation-loss-model ns3-tcp-cwnd ns3-tcp-interoperability pcap-file object-name-service random-variable-stream-generators Note the absence of the ``ns3`` build messages. ``test.py`` also supports running the test suites and examples under valgrind. Valgrind is a flexible program for debugging and profiling Linux executables. By default, valgrind runs a tool called memcheck, which performs a range of memory- checking functions, including detecting accesses to uninitialised memory, misuse of allocated memory (double frees, access after free, etc.) and detecting memory leaks. This can be selected by using the ``--grind`` option. :: $ ./test.py --grind As it runs, ``test.py`` and the programs that it runs indirectly, generate large numbers of temporary files. Usually, the content of these files is not interesting, however in some cases it can be useful (for debugging purposes) to view these files. ``test.py`` provides a ``--retain`` option which will cause these temporary files to be kept after the run is completed. The files are saved in a directory named ``testpy-output`` under a subdirectory named according to the current Coordinated Universal Time (also known as Greenwich Mean Time). :: $ ./test.py --retain Finally, ``test.py`` provides a ``--verbose`` option which will print large amounts of information about its progress. It is not expected that this will be terribly useful unless there is an error. In this case, you can get access to the standard output and standard error reported by running test suites and examples. Select verbose in the following way:: $ ./test.py --verbose All of these options can be mixed and matched. For example, to run all of the |ns3| core test suites under valgrind, in verbose mode, while generating an HTML output file, one would do:: $ ./test.py --verbose --grind --constrain=core --html=results.html TestTaxonomy ************ As mentioned above, tests are grouped into a number of broadly defined classifications to allow users to selectively run tests to address the different kinds of testing that need to be done. * Build Verification Tests * Unit Tests * System Tests * Examples * Performance Tests Moreover, each test is further classified according to the expected time needed to run it. Tests are classified as: * QUICK * EXTENSIVE * TAKES_FOREVER Note that specifying EXTENSIVE fullness will also run tests in QUICK category. Specifying TAKES_FOREVER will run tests in EXTENSIVE and QUICK categories. By default, only QUICK tests are ran. As a rule of thumb, tests that must be run to ensure |ns3| coherence should be QUICK (i.e., take a few seconds). Tests that could be skipped, but are nice to do can be EXTENSIVE; these are tests that typically need minutes. TAKES_FOREVER is left for tests that take a really long time, in the order of several minutes. The main classification goal is to be able to run the buildbots in a reasonable time, and still be able to perform more extensive tests when needed. Unit Tests ++++++++++ Unit tests are more involved tests that go into detail to make sure that a piece of code works as advertised in isolation. There is really no reason for this kind of test to be built into an |ns3| module. It turns out, for example, that the unit tests for the object name service are about the same size as the object name service code itself. Unit tests are tests that check a single bit of functionality that are not built into the |ns3| code, but live in the same directory as the code it tests. It is possible that these tests check integration of multiple implementation files in a module as well. The file src/core/test/names-test-suite.cc is an example of this kind of test. The file src/network/test/pcap-file-test-suite.cc is another example that uses a known good pcap file as a test vector file. This file is stored locally in the src/network directory. System Tests ++++++++++++ System tests are those that involve more than one module in the system. We have some of this kind of test running in our current regression framework, but they are typically overloaded examples. We provide a new place for this kind of test in the directory ``src/test``. The file ``src/test/ns3tcp/ns3tcp-loss-test-suite.cc`` is an example of this kind of test. It uses NSC TCP to test the |ns3| TCP implementation. Often there will be test vectors required for this kind of test, and they are stored in the directory where the test lives. For example, ``ns3tcp-loss-NewReno0-response-vectors.pcap`` is a file consisting of a number of TCP headers that are used as the expected responses of the |ns3| TCP under test. Note that Unit Tests are often preferable to System Tests, as they are more independent from small changes in the modules that are not the goal of the test. Examples ++++++++ The examples are tested by the framework to make sure they built and will run. Limited checking is done on examples; currently the pcap files are just written off into /tmp to be discarded. If the example runs (don't crash) and the exit status is zero, the example will pass the smoke test. Performance Tests +++++++++++++++++ Performance tests are those which exercise a particular part of the system and determine if the tests have executed to completion in a reasonable time. Running Tests ************* Tests are typically run using the high level ``test.py`` program. To get a list of the available command-line options, run ``test.py --help`` The test program ``test.py`` will run both tests and those examples that have been added to the list to check. The difference between tests and examples is as follows. Tests generally check that specific simulation output or events conforms to expected behavior. In contrast, the output of examples is not checked, and the test program merely checks the exit status of the example program to make sure that it runs without error. Briefly, to run all tests, first one must configure tests during configuration stage, and also (optionally) examples if examples are to be checked: :: $ ./ns3 configure --enable-examples --enable-tests Then, build |ns3|, and after it is built, just run ``test.py``. ``test.py -h`` will show a number of configuration options that modify the behavior of test.py. The program ``test.py`` invokes, for C++ tests and examples, a lower-level C++ program called ``test-runner`` to actually run the tests. As discussed below, this ``test-runner`` can be a helpful way to debug tests. Debugging Tests *************** The debugging of the test programs is best performed running the low-level test-runner program. The test-runner is the bridge from generic Python code to |ns3| code. It is written in C++ and uses the automatic test discovery process in the |ns3| code to find and allow execution of all of the various tests. The main reason why ``test.py`` is not suitable for debugging is that it is not allowed for logging to be turned on using the ``NS_LOG`` environmental variable when test.py runs. This limitation does not apply to the test-runner executable. Hence, if you want to see logging output from your tests, you have to run them using the test-runner directly. In order to execute the test-runner, you run it like any other |ns3| executable -- using ``ns3``. To get a list of available options, you can type:: $ ./ns3 run "test-runner --help" You should see something like the following .. sourcecode:: text Usage: /home/craigdo/repos/ns-3-allinone-test/ns-3-dev/build/utils/ns3-dev-test-runner-debug [OPTIONS] Options: --help : print these options --print-test-name-list : print the list of names of tests available --list : an alias for --print-test-name-list --print-test-types : print the type of tests along with their names --print-test-type-list : print the list of types of tests available --print-temp-dir : print name of temporary directory before running the tests --test-type=TYPE : process only tests of type TYPE --test-name=NAME : process only test whose name matches NAME --suite=NAME : an alias (here for compatibility reasons only) for --test-name=NAME --assert-on-failure : when a test fails, crash immediately (useful when running under a debugger --stop-on-failure : when a test fails, stop immediately --fullness=FULLNESS : choose the duration of tests to run: QUICK, EXTENSIVE, or TAKES_FOREVER, where EXTENSIVE includes QUICK and TAKES_FOREVER includes QUICK and EXTENSIVE (only QUICK tests are run by default) --verbose : print details of test execution --xml : format test run output as xml --tempdir=DIR : set temp dir for tests to store output files --datadir=DIR : set data dir for tests to read reference files --out=FILE : send test result to FILE instead of standard output --append=FILE : append test result to FILE instead of standard output There are a number of things available to you which will be familiar to you if you have looked at ``test.py``. This should be expected since the test- runner is just an interface between ``test.py`` and |ns3|. You may notice that example-related commands are missing here. That is because the examples are really not |ns3| tests. ``test.py`` runs them as if they were to present a unified testing environment, but they are really completely different and not to be found here. The first new option that appears here, but not in test.py is the ``--assert-on-failure`` option. This option is useful when debugging a test case when running under a debugger like ``gdb``. When selected, this option tells the underlying test case to cause a segmentation violation if an error is detected. This has the nice side-effect of causing program execution to stop (break into the debugger) when an error is detected. If you are using gdb, you could use this option something like, :: $ ./ns3 shell $ cd build/utils $ gdb ns3-dev-test-runner-debug $ run --suite=global-value --assert-on-failure If an error is then found in the global-value test suite, a segfault would be generated and the (source level) debugger would stop at the ``NS_TEST_ASSERT_MSG`` that detected the error. To run one of the tests directly from the test-runner using ``ns3``, you will need to specify the test suite to run. So you could use the shell and do:: $ ./ns3 run "test-runner --suite=pcap-file" |ns3| logging is available when you run it this way, such as:: $ NS_LOG="Packet" ./ns3 run "test-runner --suite=pcap-file" Test output +++++++++++ Many test suites need to write temporary files (such as pcap files) in the process of running the tests. The tests then need a temporary directory to write to. The Python test utility (test.py) will provide a temporary file automatically, but if run stand-alone this temporary directory must be provided. It can be annoying to continually have to provide a ``--tempdir``, so the test runner will figure one out for you if you don't provide one. It first looks for environment variables named ``TMP`` and ``TEMP`` and uses those. If neither ``TMP`` nor ``TEMP`` are defined it picks ``/tmp``. The code then tacks on an identifier indicating what created the directory (ns-3) then the time (hh.mm.ss) followed by a large random number. The test runner creates a directory of that name to be used as the temporary directory. Temporary files then go into a directory that will be named something like :: /tmp/ns-3.10.25.37.61537845 The time is provided as a hint so that you can relatively easily reconstruct what directory was used if you need to go back and look at the files that were placed in that directory. Another class of output is test output like pcap traces that are generated to compare to reference output. The test program will typically delete these after the test suites all run. To disable the deletion of test output, run ``test.py`` with the "retain" option: :: $ ./test.py -r and test output can be found in the ``testpy-output/`` directory. Reporting of test failures ++++++++++++++++++++++++++ When you run a test suite using the test-runner it will run the test and report PASS or FAIL. To run more quietly, you need to specify an output file to which the tests will write their status using the ``--out`` option. Try, :: $ ./ns3 run "test-runner --suite=pcap-file --out=myfile.txt" Debugging test suite failures +++++++++++++++++++++++++++++ To debug test crashes, such as .. sourcecode:: text CRASH: TestSuite wifi-interference You can access the underlying test-runner program via gdb as follows, and then pass the "--basedir=`pwd`" argument to run (you can also pass other arguments as needed, but basedir is the minimum needed):: $ ./ns3 run "test-runner" --command-template="gdb %s" Waf: Entering directory `/home/tomh/hg/sep09/ns-3-allinone/ns-3-dev-678/build' Waf: Leaving directory `/home/tomh/hg/sep09/ns-3-allinone/ns-3-dev-678/build' 'build' finished successfully (0.380s) GNU gdb 6.8-debian Copyright (C) 2008 Free Software Foundation, Inc. L cense GPLv3+: GNU GPL version 3 or later This is free software: you are free to change and redistribute it. There is NO WARRANTY, to the extent permitted by law. Type "show copying" and "show warranty" for details. This GDB was configured as "x86_64-linux-gnu"... (gdb) r --suite= Starting program: <..>/build/utils/ns3-dev-test-runner-debug --suite=wifi-interference [Thread debugging using libthread_db enabled] assert failed. file=../src/core/model/type-id.cc, line=138, cond="uid <= m_information.size() && uid != 0" ... Here is another example of how to use valgrind to debug a memory problem such as:: VALGR: TestSuite devices-mesh-dot11s-regression $ ./ns3 run test-runner --command-template="valgrind %s --suite=devices-mesh-dot11s-regression" Class TestRunner **************** The executables that run dedicated test programs use a TestRunner class. This class provides for automatic test registration and listing, as well as a way to execute the individual tests. Individual test suites use C++ global constructors to add themselves to a collection of test suites managed by the test runner. The test runner is used to list all of the available tests and to select a test to be run. This is a quite simple class that provides three static methods to provide or Adding and Getting test suites to a collection of tests. See the doxygen for class ``ns3::TestRunner`` for details. Test Suite ********** All |ns3| tests are classified into Test Suites and Test Cases. A test suite is a collection of test cases that completely exercise a given kind of functionality. As described above, test suites can be classified as, * Build Verification Tests * Unit Tests * System Tests * Examples * Performance Tests This classification is exported from the TestSuite class. This class is quite simple, existing only as a place to export this type and to accumulate test cases. From a user perspective, in order to create a new TestSuite in the system one only has to define a new class that inherits from class ``TestSuite`` and perform these two duties. The following code will define a new class that can be run by ``test.py`` as a ''unit'' test with the display name, ``my-test-suite-name``. .. sourcecode:: cpp class MySuite : public TestSuite { public: MyTestSuite(); }; MyTestSuite::MyTestSuite() : TestSuite("my-test-suite-name", Type::UNIT) { AddTestCase(new MyTestCase, TestCase::Duration::QUICK); } static MyTestSuite myTestSuite; The base class takes care of all of the registration and reporting required to be a good citizen in the test framework. Avoid putting initialization logic into the test suite or test case constructors. This is because an instance of the test suite is created at run time (due to the static variable above) regardless of whether the test is being run or not. Instead, the TestCase provides a virtual ``DoSetup`` method that can be specialized to perform setup before ``DoRun`` is called. Test Case ********* Individual tests are created using a TestCase class. Common models for the use of a test case include "one test case per feature", and "one test case per method." Mixtures of these models may be used. In order to create a new test case in the system, all one has to do is to inherit from the ``TestCase`` base class, override the constructor to give the test case a name and override the ``DoRun`` method to run the test. Optionally, override also the ``DoSetup`` method. .. sourcecode:: cpp class MyTestCase : public TestCase { MyTestCase(); virtual void DoSetup(); virtual void DoRun(); }; MyTestCase::MyTestCase() : TestCase("Check some bit of functionality") { } void MyTestCase::DoRun() { NS_TEST_ASSERT_MSG_EQ(true, true, "Some failure message"); } Utilities ********* There are a number of utilities of various kinds that are also part of the testing framework. Examples include a generalized pcap file useful for storing test vectors; a generic container useful for transient storage of test vectors during test execution; and tools for generating presentations based on validation and verification testing results. These utilities are not documented here, but for example, please see how the TCP tests found in ``src/test/ns3tcp/`` use pcap files and reference output.