Erlang (programming language)/Tutorials/eunit: Difference between revisions
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imported>Eric Evers mNo edit summary |
imported>Eric Evers mNo edit summary |
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start() -> | start() -> | ||
io:format(" This is a demo for eunit, the unit testing module.\n"), | io:format(" This is a demo for eunit, the unit testing module.\n"), | ||
io:format(" Now testing the | io:format(" Now testing the pow() function with eunit\n"), | ||
io:format(" Running: eunit:test( | io:format(" Running: eunit:test(pow)~n"), | ||
eunit:test(fact). | eunit:test(fact). | ||
Revision as of 10:52, 3 October 2008
Sample program that uses eunit to test a function.
-module(power). -export([pow/2, start/0]). -include_lib("../../lib/eunit/include/eunit.hrl"). % adjust your own path
pow(_,0) -> 1; pow(X,1) -> X; pow(X,N) when N>1, is_integer(N) -> X * pow(X,N-1).
start() -> io:format(" This is a demo for eunit, the unit testing module.\n"), io:format(" Now testing the pow() function with eunit\n"), io:format(" Running: eunit:test(pow)~n"), eunit:test(fact).
power_test_() -> [?_assert(pow(0,0) == 1), ?_assert(pow(1,1) == 1), ?_assert(pow(2,2) == 4), ?_assert(pow(3,3) == 27), ?_assert(pow(4,4) == 256), ?_assertException(error, function_clause, pow(-1,0.5)) ].
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Note: Default unit test functions are automatically exported by eunit % % To test function power() we compile and test. % % 2> c(power). % 3> eunit:test(pow). % All 6 tests successful. % But how does it work? % eunit:test(pow) uses fact:power_test_() to produce % a list of 6 test functions(a test suite): % 7> power:pow_test_(). % {15,#Fun<pow.1.106864721>}, % {16,#Fun<pow.2.81990874>}, % {17,#Fun<pow.3.122231603>}, % {18,#Fun<pow.4.90957845>}, % {19,#Fun<pow.5.90843223>}, % {20,#Fun<pow.4.90457845>}] % % eunit:test then runs the programs in the test suite % and reports the results. % % Note: The numbers [15,16,17,18,19] are % the line numbers of the source code that generated the % test functions. % % Assertions % % Six total tests are run. An assertion is a positive assertion % and expects the answer to be true. There are 5 positive assertions % and 1 negative assertion in the test suite. % % Negative assertions % % A negative assertion is where an error is expected. % If an error is generated, then the test succeeds. % Since this power function does not know how to do % negative bases, then it causes an error. Since an % error is expected, the test succeeds. % % assertException(error, function_clause, pow(-1,0.5)) % % is an example of a negative assertion. % An error generates an exception. An exception is % is a type of high level error message. % % See Exceptions % for more details. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
Unit tests as internal documentation
Unit tests provide a useful method of internal documentation that is often easy to maintain. The maintenance of documentation can often be a problem as programs evolve over time. As long as the unit test works, the unit test serves as a nice suite of example programs that can aid comprehension. For the purpose of internal documentation and other reasons at least one negative assertion is included to form a complete test suite. A negative assertion can show the limits of the domain or the range of a function, or even its time complexity if one includes a timeout bound on computation time.
Software engineering
Unit tests can help one keep an eye on side-effects during program development. Fixing a bug for some input may cause a bug with some previously working input. Unit testing can help with the organization of a program and inspire new solutions.
Note: for the program to work you will need to install and perhaps compile the eunit module, and set up your path to include it.