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  1. # Advanced googletest Topics
  2. ## Introduction
  3. Now that you have read the [googletest Primer](primer.md) and learned how to
  4. write tests using googletest, it's time to learn some new tricks. This document
  5. will show you more assertions as well as how to construct complex failure
  6. messages, propagate fatal failures, reuse and speed up your test fixtures, and
  7. use various flags with your tests.
  8. ## More Assertions
  9. This section covers some less frequently used, but still significant,
  10. assertions.
  11. ### Explicit Success and Failure
  12. See [Explicit Success and Failure](reference/assertions.md#success-failure) in
  13. the Assertions Reference.
  14. ### Exception Assertions
  15. See [Exception Assertions](reference/assertions.md#exceptions) in the Assertions
  16. Reference.
  17. ### Predicate Assertions for Better Error Messages
  18. Even though googletest has a rich set of assertions, they can never be complete,
  19. as it's impossible (nor a good idea) to anticipate all scenarios a user might
  20. run into. Therefore, sometimes a user has to use `EXPECT_TRUE()` to check a
  21. complex expression, for lack of a better macro. This has the problem of not
  22. showing you the values of the parts of the expression, making it hard to
  23. understand what went wrong. As a workaround, some users choose to construct the
  24. failure message by themselves, streaming it into `EXPECT_TRUE()`. However, this
  25. is awkward especially when the expression has side-effects or is expensive to
  26. evaluate.
  27. googletest gives you three different options to solve this problem:
  28. #### Using an Existing Boolean Function
  29. If you already have a function or functor that returns `bool` (or a type that
  30. can be implicitly converted to `bool`), you can use it in a *predicate
  31. assertion* to get the function arguments printed for free. See
  32. [`EXPECT_PRED*`](reference/assertions.md#EXPECT_PRED) in the Assertions
  33. Reference for details.
  34. #### Using a Function That Returns an AssertionResult
  35. While `EXPECT_PRED*()` and friends are handy for a quick job, the syntax is not
  36. satisfactory: you have to use different macros for different arities, and it
  37. feels more like Lisp than C++. The `::testing::AssertionResult` class solves
  38. this problem.
  39. An `AssertionResult` object represents the result of an assertion (whether it's
  40. a success or a failure, and an associated message). You can create an
  41. `AssertionResult` using one of these factory functions:
  42. ```c++
  43. namespace testing {
  44. // Returns an AssertionResult object to indicate that an assertion has
  45. // succeeded.
  46. AssertionResult AssertionSuccess();
  47. // Returns an AssertionResult object to indicate that an assertion has
  48. // failed.
  49. AssertionResult AssertionFailure();
  50. }
  51. ```
  52. You can then use the `<<` operator to stream messages to the `AssertionResult`
  53. object.
  54. To provide more readable messages in Boolean assertions (e.g. `EXPECT_TRUE()`),
  55. write a predicate function that returns `AssertionResult` instead of `bool`. For
  56. example, if you define `IsEven()` as:
  57. ```c++
  58. testing::AssertionResult IsEven(int n) {
  59. if ((n % 2) == 0)
  60. return testing::AssertionSuccess();
  61. else
  62. return testing::AssertionFailure() << n << " is odd";
  63. }
  64. ```
  65. instead of:
  66. ```c++
  67. bool IsEven(int n) {
  68. return (n % 2) == 0;
  69. }
  70. ```
  71. the failed assertion `EXPECT_TRUE(IsEven(Fib(4)))` will print:
  72. ```none
  73. Value of: IsEven(Fib(4))
  74. Actual: false (3 is odd)
  75. Expected: true
  76. ```
  77. instead of a more opaque
  78. ```none
  79. Value of: IsEven(Fib(4))
  80. Actual: false
  81. Expected: true
  82. ```
  83. If you want informative messages in `EXPECT_FALSE` and `ASSERT_FALSE` as well
  84. (one third of Boolean assertions in the Google code base are negative ones), and
  85. are fine with making the predicate slower in the success case, you can supply a
  86. success message:
  87. ```c++
  88. testing::AssertionResult IsEven(int n) {
  89. if ((n % 2) == 0)
  90. return testing::AssertionSuccess() << n << " is even";
  91. else
  92. return testing::AssertionFailure() << n << " is odd";
  93. }
  94. ```
  95. Then the statement `EXPECT_FALSE(IsEven(Fib(6)))` will print
  96. ```none
  97. Value of: IsEven(Fib(6))
  98. Actual: true (8 is even)
  99. Expected: false
  100. ```
  101. #### Using a Predicate-Formatter
  102. If you find the default message generated by
  103. [`EXPECT_PRED*`](reference/assertions.md#EXPECT_PRED) and
  104. [`EXPECT_TRUE`](reference/assertions.md#EXPECT_TRUE) unsatisfactory, or some
  105. arguments to your predicate do not support streaming to `ostream`, you can
  106. instead use *predicate-formatter assertions* to *fully* customize how the
  107. message is formatted. See
  108. [`EXPECT_PRED_FORMAT*`](reference/assertions.md#EXPECT_PRED_FORMAT) in the
  109. Assertions Reference for details.
  110. ### Floating-Point Comparison
  111. See [Floating-Point Comparison](reference/assertions.md#floating-point) in the
  112. Assertions Reference.
  113. #### Floating-Point Predicate-Format Functions
  114. Some floating-point operations are useful, but not that often used. In order to
  115. avoid an explosion of new macros, we provide them as predicate-format functions
  116. that can be used in the predicate assertion macro
  117. [`EXPECT_PRED_FORMAT2`](reference/assertions.md#EXPECT_PRED_FORMAT), for
  118. example:
  119. ```c++
  120. EXPECT_PRED_FORMAT2(testing::FloatLE, val1, val2);
  121. EXPECT_PRED_FORMAT2(testing::DoubleLE, val1, val2);
  122. ```
  123. The above code verifies that `val1` is less than, or approximately equal to,
  124. `val2`.
  125. ### Asserting Using gMock Matchers
  126. See [`EXPECT_THAT`](reference/assertions.md#EXPECT_THAT) in the Assertions
  127. Reference.
  128. ### More String Assertions
  129. (Please read the [previous](#asserting-using-gmock-matchers) section first if
  130. you haven't.)
  131. You can use the gMock [string matchers](reference/matchers.md#string-matchers)
  132. with [`EXPECT_THAT`](reference/assertions.md#EXPECT_THAT) to do more string
  133. comparison tricks (sub-string, prefix, suffix, regular expression, and etc). For
  134. example,
  135. ```c++
  136. using ::testing::HasSubstr;
  137. using ::testing::MatchesRegex;
  138. ...
  139. ASSERT_THAT(foo_string, HasSubstr("needle"));
  140. EXPECT_THAT(bar_string, MatchesRegex("\\w*\\d+"));
  141. ```
  142. ### Windows HRESULT assertions
  143. See [Windows HRESULT Assertions](reference/assertions.md#HRESULT) in the
  144. Assertions Reference.
  145. ### Type Assertions
  146. You can call the function
  147. ```c++
  148. ::testing::StaticAssertTypeEq<T1, T2>();
  149. ```
  150. to assert that types `T1` and `T2` are the same. The function does nothing if
  151. the assertion is satisfied. If the types are different, the function call will
  152. fail to compile, the compiler error message will say that
  153. `T1 and T2 are not the same type` and most likely (depending on the compiler)
  154. show you the actual values of `T1` and `T2`. This is mainly useful inside
  155. template code.
  156. **Caveat**: When used inside a member function of a class template or a function
  157. template, `StaticAssertTypeEq<T1, T2>()` is effective only if the function is
  158. instantiated. For example, given:
  159. ```c++
  160. template <typename T> class Foo {
  161. public:
  162. void Bar() { testing::StaticAssertTypeEq<int, T>(); }
  163. };
  164. ```
  165. the code:
  166. ```c++
  167. void Test1() { Foo<bool> foo; }
  168. ```
  169. will not generate a compiler error, as `Foo<bool>::Bar()` is never actually
  170. instantiated. Instead, you need:
  171. ```c++
  172. void Test2() { Foo<bool> foo; foo.Bar(); }
  173. ```
  174. to cause a compiler error.
  175. ### Assertion Placement
  176. You can use assertions in any C++ function. In particular, it doesn't have to be
  177. a method of the test fixture class. The one constraint is that assertions that
  178. generate a fatal failure (`FAIL*` and `ASSERT_*`) can only be used in
  179. void-returning functions. This is a consequence of Google's not using
  180. exceptions. By placing it in a non-void function you'll get a confusing compile
  181. error like `"error: void value not ignored as it ought to be"` or `"cannot
  182. initialize return object of type 'bool' with an rvalue of type 'void'"` or
  183. `"error: no viable conversion from 'void' to 'string'"`.
  184. If you need to use fatal assertions in a function that returns non-void, one
  185. option is to make the function return the value in an out parameter instead. For
  186. example, you can rewrite `T2 Foo(T1 x)` to `void Foo(T1 x, T2* result)`. You
  187. need to make sure that `*result` contains some sensible value even when the
  188. function returns prematurely. As the function now returns `void`, you can use
  189. any assertion inside of it.
  190. If changing the function's type is not an option, you should just use assertions
  191. that generate non-fatal failures, such as `ADD_FAILURE*` and `EXPECT_*`.
  192. {: .callout .note}
  193. NOTE: Constructors and destructors are not considered void-returning functions,
  194. according to the C++ language specification, and so you may not use fatal
  195. assertions in them; you'll get a compilation error if you try. Instead, either
  196. call `abort` and crash the entire test executable, or put the fatal assertion in
  197. a `SetUp`/`TearDown` function; see
  198. [constructor/destructor vs. `SetUp`/`TearDown`](faq.md#CtorVsSetUp)
  199. {: .callout .warning}
  200. WARNING: A fatal assertion in a helper function (private void-returning method)
  201. called from a constructor or destructor does not terminate the current test, as
  202. your intuition might suggest: it merely returns from the constructor or
  203. destructor early, possibly leaving your object in a partially-constructed or
  204. partially-destructed state! You almost certainly want to `abort` or use
  205. `SetUp`/`TearDown` instead.
  206. ## Skipping test execution
  207. Related to the assertions `SUCCEED()` and `FAIL()`, you can prevent further test
  208. execution at runtime with the `GTEST_SKIP()` macro. This is useful when you need
  209. to check for preconditions of the system under test during runtime and skip
  210. tests in a meaningful way.
  211. `GTEST_SKIP()` can be used in individual test cases or in the `SetUp()` methods
  212. of classes derived from either `::testing::Environment` or `::testing::Test`.
  213. For example:
  214. ```c++
  215. TEST(SkipTest, DoesSkip) {
  216. GTEST_SKIP() << "Skipping single test";
  217. EXPECT_EQ(0, 1); // Won't fail; it won't be executed
  218. }
  219. class SkipFixture : public ::testing::Test {
  220. protected:
  221. void SetUp() override {
  222. GTEST_SKIP() << "Skipping all tests for this fixture";
  223. }
  224. };
  225. // Tests for SkipFixture won't be executed.
  226. TEST_F(SkipFixture, SkipsOneTest) {
  227. EXPECT_EQ(5, 7); // Won't fail
  228. }
  229. ```
  230. As with assertion macros, you can stream a custom message into `GTEST_SKIP()`.
  231. ## Teaching googletest How to Print Your Values
  232. When a test assertion such as `EXPECT_EQ` fails, googletest prints the argument
  233. values to help you debug. It does this using a user-extensible value printer.
  234. This printer knows how to print built-in C++ types, native arrays, STL
  235. containers, and any type that supports the `<<` operator. For other types, it
  236. prints the raw bytes in the value and hopes that you the user can figure it out.
  237. As mentioned earlier, the printer is *extensible*. That means you can teach it
  238. to do a better job at printing your particular type than to dump the bytes. To
  239. do that, define `<<` for your type:
  240. ```c++
  241. #include <ostream>
  242. namespace foo {
  243. class Bar { // We want googletest to be able to print instances of this.
  244. ...
  245. // Create a free inline friend function.
  246. friend std::ostream& operator<<(std::ostream& os, const Bar& bar) {
  247. return os << bar.DebugString(); // whatever needed to print bar to os
  248. }
  249. };
  250. // If you can't declare the function in the class it's important that the
  251. // << operator is defined in the SAME namespace that defines Bar. C++'s look-up
  252. // rules rely on that.
  253. std::ostream& operator<<(std::ostream& os, const Bar& bar) {
  254. return os << bar.DebugString(); // whatever needed to print bar to os
  255. }
  256. } // namespace foo
  257. ```
  258. Sometimes, this might not be an option: your team may consider it bad style to
  259. have a `<<` operator for `Bar`, or `Bar` may already have a `<<` operator that
  260. doesn't do what you want (and you cannot change it). If so, you can instead
  261. define a `PrintTo()` function like this:
  262. ```c++
  263. #include <ostream>
  264. namespace foo {
  265. class Bar {
  266. ...
  267. friend void PrintTo(const Bar& bar, std::ostream* os) {
  268. *os << bar.DebugString(); // whatever needed to print bar to os
  269. }
  270. };
  271. // If you can't declare the function in the class it's important that PrintTo()
  272. // is defined in the SAME namespace that defines Bar. C++'s look-up rules rely
  273. // on that.
  274. void PrintTo(const Bar& bar, std::ostream* os) {
  275. *os << bar.DebugString(); // whatever needed to print bar to os
  276. }
  277. } // namespace foo
  278. ```
  279. If you have defined both `<<` and `PrintTo()`, the latter will be used when
  280. googletest is concerned. This allows you to customize how the value appears in
  281. googletest's output without affecting code that relies on the behavior of its
  282. `<<` operator.
  283. If you want to print a value `x` using googletest's value printer yourself, just
  284. call `::testing::PrintToString(x)`, which returns an `std::string`:
  285. ```c++
  286. vector<pair<Bar, int> > bar_ints = GetBarIntVector();
  287. EXPECT_TRUE(IsCorrectBarIntVector(bar_ints))
  288. << "bar_ints = " << testing::PrintToString(bar_ints);
  289. ```
  290. ## Death Tests
  291. In many applications, there are assertions that can cause application failure if
  292. a condition is not met. These sanity checks, which ensure that the program is in
  293. a known good state, are there to fail at the earliest possible time after some
  294. program state is corrupted. If the assertion checks the wrong condition, then
  295. the program may proceed in an erroneous state, which could lead to memory
  296. corruption, security holes, or worse. Hence it is vitally important to test that
  297. such assertion statements work as expected.
  298. Since these precondition checks cause the processes to die, we call such tests
  299. _death tests_. More generally, any test that checks that a program terminates
  300. (except by throwing an exception) in an expected fashion is also a death test.
  301. Note that if a piece of code throws an exception, we don't consider it "death"
  302. for the purpose of death tests, as the caller of the code could catch the
  303. exception and avoid the crash. If you want to verify exceptions thrown by your
  304. code, see [Exception Assertions](#ExceptionAssertions).
  305. If you want to test `EXPECT_*()/ASSERT_*()` failures in your test code, see
  306. ["Catching" Failures](#catching-failures).
  307. ### How to Write a Death Test
  308. GoogleTest provides assertion macros to support death tests. See
  309. [Death Assertions](reference/assertions.md#death) in the Assertions Reference
  310. for details.
  311. To write a death test, simply use one of the macros inside your test function.
  312. For example,
  313. ```c++
  314. TEST(MyDeathTest, Foo) {
  315. // This death test uses a compound statement.
  316. ASSERT_DEATH({
  317. int n = 5;
  318. Foo(&n);
  319. }, "Error on line .* of Foo()");
  320. }
  321. TEST(MyDeathTest, NormalExit) {
  322. EXPECT_EXIT(NormalExit(), testing::ExitedWithCode(0), "Success");
  323. }
  324. TEST(MyDeathTest, KillProcess) {
  325. EXPECT_EXIT(KillProcess(), testing::KilledBySignal(SIGKILL),
  326. "Sending myself unblockable signal");
  327. }
  328. ```
  329. verifies that:
  330. * calling `Foo(5)` causes the process to die with the given error message,
  331. * calling `NormalExit()` causes the process to print `"Success"` to stderr and
  332. exit with exit code 0, and
  333. * calling `KillProcess()` kills the process with signal `SIGKILL`.
  334. The test function body may contain other assertions and statements as well, if
  335. necessary.
  336. Note that a death test only cares about three things:
  337. 1. does `statement` abort or exit the process?
  338. 2. (in the case of `ASSERT_EXIT` and `EXPECT_EXIT`) does the exit status
  339. satisfy `predicate`? Or (in the case of `ASSERT_DEATH` and `EXPECT_DEATH`)
  340. is the exit status non-zero? And
  341. 3. does the stderr output match `matcher`?
  342. In particular, if `statement` generates an `ASSERT_*` or `EXPECT_*` failure, it
  343. will **not** cause the death test to fail, as googletest assertions don't abort
  344. the process.
  345. ### Death Test Naming
  346. {: .callout .important}
  347. IMPORTANT: We strongly recommend you to follow the convention of naming your
  348. **test suite** (not test) `*DeathTest` when it contains a death test, as
  349. demonstrated in the above example. The
  350. [Death Tests And Threads](#death-tests-and-threads) section below explains why.
  351. If a test fixture class is shared by normal tests and death tests, you can use
  352. `using` or `typedef` to introduce an alias for the fixture class and avoid
  353. duplicating its code:
  354. ```c++
  355. class FooTest : public testing::Test { ... };
  356. using FooDeathTest = FooTest;
  357. TEST_F(FooTest, DoesThis) {
  358. // normal test
  359. }
  360. TEST_F(FooDeathTest, DoesThat) {
  361. // death test
  362. }
  363. ```
  364. ### Regular Expression Syntax
  365. On POSIX systems (e.g. Linux, Cygwin, and Mac), googletest uses the
  366. [POSIX extended regular expression](http://www.opengroup.org/onlinepubs/009695399/basedefs/xbd_chap09.html#tag_09_04)
  367. syntax. To learn about this syntax, you may want to read this
  368. [Wikipedia entry](http://en.wikipedia.org/wiki/Regular_expression#POSIX_Extended_Regular_Expressions).
  369. On Windows, googletest uses its own simple regular expression implementation. It
  370. lacks many features. For example, we don't support union (`"x|y"`), grouping
  371. (`"(xy)"`), brackets (`"[xy]"`), and repetition count (`"x{5,7}"`), among
  372. others. Below is what we do support (`A` denotes a literal character, period
  373. (`.`), or a single `\\ ` escape sequence; `x` and `y` denote regular
  374. expressions.):
  375. Expression | Meaning
  376. ---------- | --------------------------------------------------------------
  377. `c` | matches any literal character `c`
  378. `\\d` | matches any decimal digit
  379. `\\D` | matches any character that's not a decimal digit
  380. `\\f` | matches `\f`
  381. `\\n` | matches `\n`
  382. `\\r` | matches `\r`
  383. `\\s` | matches any ASCII whitespace, including `\n`
  384. `\\S` | matches any character that's not a whitespace
  385. `\\t` | matches `\t`
  386. `\\v` | matches `\v`
  387. `\\w` | matches any letter, `_`, or decimal digit
  388. `\\W` | matches any character that `\\w` doesn't match
  389. `\\c` | matches any literal character `c`, which must be a punctuation
  390. `.` | matches any single character except `\n`
  391. `A?` | matches 0 or 1 occurrences of `A`
  392. `A*` | matches 0 or many occurrences of `A`
  393. `A+` | matches 1 or many occurrences of `A`
  394. `^` | matches the beginning of a string (not that of each line)
  395. `$` | matches the end of a string (not that of each line)
  396. `xy` | matches `x` followed by `y`
  397. To help you determine which capability is available on your system, googletest
  398. defines macros to govern which regular expression it is using. The macros are:
  399. `GTEST_USES_SIMPLE_RE=1` or `GTEST_USES_POSIX_RE=1`. If you want your death
  400. tests to work in all cases, you can either `#if` on these macros or use the more
  401. limited syntax only.
  402. ### How It Works
  403. See [Death Assertions](reference/assertions.md#death) in the Assertions
  404. Reference.
  405. ### Death Tests And Threads
  406. The reason for the two death test styles has to do with thread safety. Due to
  407. well-known problems with forking in the presence of threads, death tests should
  408. be run in a single-threaded context. Sometimes, however, it isn't feasible to
  409. arrange that kind of environment. For example, statically-initialized modules
  410. may start threads before main is ever reached. Once threads have been created,
  411. it may be difficult or impossible to clean them up.
  412. googletest has three features intended to raise awareness of threading issues.
  413. 1. A warning is emitted if multiple threads are running when a death test is
  414. encountered.
  415. 2. Test suites with a name ending in "DeathTest" are run before all other
  416. tests.
  417. 3. It uses `clone()` instead of `fork()` to spawn the child process on Linux
  418. (`clone()` is not available on Cygwin and Mac), as `fork()` is more likely
  419. to cause the child to hang when the parent process has multiple threads.
  420. It's perfectly fine to create threads inside a death test statement; they are
  421. executed in a separate process and cannot affect the parent.
  422. ### Death Test Styles
  423. The "threadsafe" death test style was introduced in order to help mitigate the
  424. risks of testing in a possibly multithreaded environment. It trades increased
  425. test execution time (potentially dramatically so) for improved thread safety.
  426. The automated testing framework does not set the style flag. You can choose a
  427. particular style of death tests by setting the flag programmatically:
  428. ```c++
  429. testing::FLAGS_gtest_death_test_style="threadsafe"
  430. ```
  431. You can do this in `main()` to set the style for all death tests in the binary,
  432. or in individual tests. Recall that flags are saved before running each test and
  433. restored afterwards, so you need not do that yourself. For example:
  434. ```c++
  435. int main(int argc, char** argv) {
  436. testing::InitGoogleTest(&argc, argv);
  437. testing::FLAGS_gtest_death_test_style = "fast";
  438. return RUN_ALL_TESTS();
  439. }
  440. TEST(MyDeathTest, TestOne) {
  441. testing::FLAGS_gtest_death_test_style = "threadsafe";
  442. // This test is run in the "threadsafe" style:
  443. ASSERT_DEATH(ThisShouldDie(), "");
  444. }
  445. TEST(MyDeathTest, TestTwo) {
  446. // This test is run in the "fast" style:
  447. ASSERT_DEATH(ThisShouldDie(), "");
  448. }
  449. ```
  450. ### Caveats
  451. The `statement` argument of `ASSERT_EXIT()` can be any valid C++ statement. If
  452. it leaves the current function via a `return` statement or by throwing an
  453. exception, the death test is considered to have failed. Some googletest macros
  454. may return from the current function (e.g. `ASSERT_TRUE()`), so be sure to avoid
  455. them in `statement`.
  456. Since `statement` runs in the child process, any in-memory side effect (e.g.
  457. modifying a variable, releasing memory, etc) it causes will *not* be observable
  458. in the parent process. In particular, if you release memory in a death test,
  459. your program will fail the heap check as the parent process will never see the
  460. memory reclaimed. To solve this problem, you can
  461. 1. try not to free memory in a death test;
  462. 2. free the memory again in the parent process; or
  463. 3. do not use the heap checker in your program.
  464. Due to an implementation detail, you cannot place multiple death test assertions
  465. on the same line; otherwise, compilation will fail with an unobvious error
  466. message.
  467. Despite the improved thread safety afforded by the "threadsafe" style of death
  468. test, thread problems such as deadlock are still possible in the presence of
  469. handlers registered with `pthread_atfork(3)`.
  470. ## Using Assertions in Sub-routines
  471. {: .callout .note}
  472. Note: If you want to put a series of test assertions in a subroutine to check
  473. for a complex condition, consider using
  474. [a custom GMock matcher](gmock_cook_book.md#NewMatchers)
  475. instead. This lets you provide a more readable error message in case of failure
  476. and avoid all of the issues described below.
  477. ### Adding Traces to Assertions
  478. If a test sub-routine is called from several places, when an assertion inside it
  479. fails, it can be hard to tell which invocation of the sub-routine the failure is
  480. from. You can alleviate this problem using extra logging or custom failure
  481. messages, but that usually clutters up your tests. A better solution is to use
  482. the `SCOPED_TRACE` macro or the `ScopedTrace` utility:
  483. ```c++
  484. SCOPED_TRACE(message);
  485. ```
  486. ```c++
  487. ScopedTrace trace("file_path", line_number, message);
  488. ```
  489. where `message` can be anything streamable to `std::ostream`. `SCOPED_TRACE`
  490. macro will cause the current file name, line number, and the given message to be
  491. added in every failure message. `ScopedTrace` accepts explicit file name and
  492. line number in arguments, which is useful for writing test helpers. The effect
  493. will be undone when the control leaves the current lexical scope.
  494. For example,
  495. ```c++
  496. 10: void Sub1(int n) {
  497. 11: EXPECT_EQ(Bar(n), 1);
  498. 12: EXPECT_EQ(Bar(n + 1), 2);
  499. 13: }
  500. 14:
  501. 15: TEST(FooTest, Bar) {
  502. 16: {
  503. 17: SCOPED_TRACE("A"); // This trace point will be included in
  504. 18: // every failure in this scope.
  505. 19: Sub1(1);
  506. 20: }
  507. 21: // Now it won't.
  508. 22: Sub1(9);
  509. 23: }
  510. ```
  511. could result in messages like these:
  512. ```none
  513. path/to/foo_test.cc:11: Failure
  514. Value of: Bar(n)
  515. Expected: 1
  516. Actual: 2
  517. Google Test trace:
  518. path/to/foo_test.cc:17: A
  519. path/to/foo_test.cc:12: Failure
  520. Value of: Bar(n + 1)
  521. Expected: 2
  522. Actual: 3
  523. ```
  524. Without the trace, it would've been difficult to know which invocation of
  525. `Sub1()` the two failures come from respectively. (You could add an extra
  526. message to each assertion in `Sub1()` to indicate the value of `n`, but that's
  527. tedious.)
  528. Some tips on using `SCOPED_TRACE`:
  529. 1. With a suitable message, it's often enough to use `SCOPED_TRACE` at the
  530. beginning of a sub-routine, instead of at each call site.
  531. 2. When calling sub-routines inside a loop, make the loop iterator part of the
  532. message in `SCOPED_TRACE` such that you can know which iteration the failure
  533. is from.
  534. 3. Sometimes the line number of the trace point is enough for identifying the
  535. particular invocation of a sub-routine. In this case, you don't have to
  536. choose a unique message for `SCOPED_TRACE`. You can simply use `""`.
  537. 4. You can use `SCOPED_TRACE` in an inner scope when there is one in the outer
  538. scope. In this case, all active trace points will be included in the failure
  539. messages, in reverse order they are encountered.
  540. 5. The trace dump is clickable in Emacs - hit `return` on a line number and
  541. you'll be taken to that line in the source file!
  542. ### Propagating Fatal Failures
  543. A common pitfall when using `ASSERT_*` and `FAIL*` is not understanding that
  544. when they fail they only abort the _current function_, not the entire test. For
  545. example, the following test will segfault:
  546. ```c++
  547. void Subroutine() {
  548. // Generates a fatal failure and aborts the current function.
  549. ASSERT_EQ(1, 2);
  550. // The following won't be executed.
  551. ...
  552. }
  553. TEST(FooTest, Bar) {
  554. Subroutine(); // The intended behavior is for the fatal failure
  555. // in Subroutine() to abort the entire test.
  556. // The actual behavior: the function goes on after Subroutine() returns.
  557. int* p = nullptr;
  558. *p = 3; // Segfault!
  559. }
  560. ```
  561. To alleviate this, googletest provides three different solutions. You could use
  562. either exceptions, the `(ASSERT|EXPECT)_NO_FATAL_FAILURE` assertions or the
  563. `HasFatalFailure()` function. They are described in the following two
  564. subsections.
  565. #### Asserting on Subroutines with an exception
  566. The following code can turn ASSERT-failure into an exception:
  567. ```c++
  568. class ThrowListener : public testing::EmptyTestEventListener {
  569. void OnTestPartResult(const testing::TestPartResult& result) override {
  570. if (result.type() == testing::TestPartResult::kFatalFailure) {
  571. throw testing::AssertionException(result);
  572. }
  573. }
  574. };
  575. int main(int argc, char** argv) {
  576. ...
  577. testing::UnitTest::GetInstance()->listeners().Append(new ThrowListener);
  578. return RUN_ALL_TESTS();
  579. }
  580. ```
  581. This listener should be added after other listeners if you have any, otherwise
  582. they won't see failed `OnTestPartResult`.
  583. #### Asserting on Subroutines
  584. As shown above, if your test calls a subroutine that has an `ASSERT_*` failure
  585. in it, the test will continue after the subroutine returns. This may not be what
  586. you want.
  587. Often people want fatal failures to propagate like exceptions. For that
  588. googletest offers the following macros:
  589. Fatal assertion | Nonfatal assertion | Verifies
  590. ------------------------------------- | ------------------------------------- | --------
  591. `ASSERT_NO_FATAL_FAILURE(statement);` | `EXPECT_NO_FATAL_FAILURE(statement);` | `statement` doesn't generate any new fatal failures in the current thread.
  592. Only failures in the thread that executes the assertion are checked to determine
  593. the result of this type of assertions. If `statement` creates new threads,
  594. failures in these threads are ignored.
  595. Examples:
  596. ```c++
  597. ASSERT_NO_FATAL_FAILURE(Foo());
  598. int i;
  599. EXPECT_NO_FATAL_FAILURE({
  600. i = Bar();
  601. });
  602. ```
  603. Assertions from multiple threads are currently not supported on Windows.
  604. #### Checking for Failures in the Current Test
  605. `HasFatalFailure()` in the `::testing::Test` class returns `true` if an
  606. assertion in the current test has suffered a fatal failure. This allows
  607. functions to catch fatal failures in a sub-routine and return early.
  608. ```c++
  609. class Test {
  610. public:
  611. ...
  612. static bool HasFatalFailure();
  613. };
  614. ```
  615. The typical usage, which basically simulates the behavior of a thrown exception,
  616. is:
  617. ```c++
  618. TEST(FooTest, Bar) {
  619. Subroutine();
  620. // Aborts if Subroutine() had a fatal failure.
  621. if (HasFatalFailure()) return;
  622. // The following won't be executed.
  623. ...
  624. }
  625. ```
  626. If `HasFatalFailure()` is used outside of `TEST()` , `TEST_F()` , or a test
  627. fixture, you must add the `::testing::Test::` prefix, as in:
  628. ```c++
  629. if (testing::Test::HasFatalFailure()) return;
  630. ```
  631. Similarly, `HasNonfatalFailure()` returns `true` if the current test has at
  632. least one non-fatal failure, and `HasFailure()` returns `true` if the current
  633. test has at least one failure of either kind.
  634. ## Logging Additional Information
  635. In your test code, you can call `RecordProperty("key", value)` to log additional
  636. information, where `value` can be either a string or an `int`. The *last* value
  637. recorded for a key will be emitted to the
  638. [XML output](#generating-an-xml-report) if you specify one. For example, the
  639. test
  640. ```c++
  641. TEST_F(WidgetUsageTest, MinAndMaxWidgets) {
  642. RecordProperty("MaximumWidgets", ComputeMaxUsage());
  643. RecordProperty("MinimumWidgets", ComputeMinUsage());
  644. }
  645. ```
  646. will output XML like this:
  647. ```xml
  648. ...
  649. <testcase name="MinAndMaxWidgets" status="run" time="0.006" classname="WidgetUsageTest" MaximumWidgets="12" MinimumWidgets="9" />
  650. ...
  651. ```
  652. {: .callout .note}
  653. > NOTE:
  654. >
  655. > * `RecordProperty()` is a static member of the `Test` class. Therefore it
  656. > needs to be prefixed with `::testing::Test::` if used outside of the
  657. > `TEST` body and the test fixture class.
  658. > * *`key`* must be a valid XML attribute name, and cannot conflict with the
  659. > ones already used by googletest (`name`, `status`, `time`, `classname`,
  660. > `type_param`, and `value_param`).
  661. > * Calling `RecordProperty()` outside of the lifespan of a test is allowed.
  662. > If it's called outside of a test but between a test suite's
  663. > `SetUpTestSuite()` and `TearDownTestSuite()` methods, it will be
  664. > attributed to the XML element for the test suite. If it's called outside
  665. > of all test suites (e.g. in a test environment), it will be attributed to
  666. > the top-level XML element.
  667. ## Sharing Resources Between Tests in the Same Test Suite
  668. googletest creates a new test fixture object for each test in order to make
  669. tests independent and easier to debug. However, sometimes tests use resources
  670. that are expensive to set up, making the one-copy-per-test model prohibitively
  671. expensive.
  672. If the tests don't change the resource, there's no harm in their sharing a
  673. single resource copy. So, in addition to per-test set-up/tear-down, googletest
  674. also supports per-test-suite set-up/tear-down. To use it:
  675. 1. In your test fixture class (say `FooTest` ), declare as `static` some member
  676. variables to hold the shared resources.
  677. 2. Outside your test fixture class (typically just below it), define those
  678. member variables, optionally giving them initial values.
  679. 3. In the same test fixture class, define a `static void SetUpTestSuite()`
  680. function (remember not to spell it as **`SetupTestSuite`** with a small
  681. `u`!) to set up the shared resources and a `static void TearDownTestSuite()`
  682. function to tear them down.
  683. That's it! googletest automatically calls `SetUpTestSuite()` before running the
  684. *first test* in the `FooTest` test suite (i.e. before creating the first
  685. `FooTest` object), and calls `TearDownTestSuite()` after running the *last test*
  686. in it (i.e. after deleting the last `FooTest` object). In between, the tests can
  687. use the shared resources.
  688. Remember that the test order is undefined, so your code can't depend on a test
  689. preceding or following another. Also, the tests must either not modify the state
  690. of any shared resource, or, if they do modify the state, they must restore the
  691. state to its original value before passing control to the next test.
  692. Here's an example of per-test-suite set-up and tear-down:
  693. ```c++
  694. class FooTest : public testing::Test {
  695. protected:
  696. // Per-test-suite set-up.
  697. // Called before the first test in this test suite.
  698. // Can be omitted if not needed.
  699. static void SetUpTestSuite() {
  700. shared_resource_ = new ...;
  701. }
  702. // Per-test-suite tear-down.
  703. // Called after the last test in this test suite.
  704. // Can be omitted if not needed.
  705. static void TearDownTestSuite() {
  706. delete shared_resource_;
  707. shared_resource_ = nullptr;
  708. }
  709. // You can define per-test set-up logic as usual.
  710. void SetUp() override { ... }
  711. // You can define per-test tear-down logic as usual.
  712. void TearDown() override { ... }
  713. // Some expensive resource shared by all tests.
  714. static T* shared_resource_;
  715. };
  716. T* FooTest::shared_resource_ = nullptr;
  717. TEST_F(FooTest, Test1) {
  718. ... you can refer to shared_resource_ here ...
  719. }
  720. TEST_F(FooTest, Test2) {
  721. ... you can refer to shared_resource_ here ...
  722. }
  723. ```
  724. {: .callout .note}
  725. NOTE: Though the above code declares `SetUpTestSuite()` protected, it may
  726. sometimes be necessary to declare it public, such as when using it with
  727. `TEST_P`.
  728. ## Global Set-Up and Tear-Down
  729. Just as you can do set-up and tear-down at the test level and the test suite
  730. level, you can also do it at the test program level. Here's how.
  731. First, you subclass the `::testing::Environment` class to define a test
  732. environment, which knows how to set-up and tear-down:
  733. ```c++
  734. class Environment : public ::testing::Environment {
  735. public:
  736. ~Environment() override {}
  737. // Override this to define how to set up the environment.
  738. void SetUp() override {}
  739. // Override this to define how to tear down the environment.
  740. void TearDown() override {}
  741. };
  742. ```
  743. Then, you register an instance of your environment class with googletest by
  744. calling the `::testing::AddGlobalTestEnvironment()` function:
  745. ```c++
  746. Environment* AddGlobalTestEnvironment(Environment* env);
  747. ```
  748. Now, when `RUN_ALL_TESTS()` is called, it first calls the `SetUp()` method of
  749. each environment object, then runs the tests if none of the environments
  750. reported fatal failures and `GTEST_SKIP()` was not called. `RUN_ALL_TESTS()`
  751. always calls `TearDown()` with each environment object, regardless of whether or
  752. not the tests were run.
  753. It's OK to register multiple environment objects. In this suite, their `SetUp()`
  754. will be called in the order they are registered, and their `TearDown()` will be
  755. called in the reverse order.
  756. Note that googletest takes ownership of the registered environment objects.
  757. Therefore **do not delete them** by yourself.
  758. You should call `AddGlobalTestEnvironment()` before `RUN_ALL_TESTS()` is called,
  759. probably in `main()`. If you use `gtest_main`, you need to call this before
  760. `main()` starts for it to take effect. One way to do this is to define a global
  761. variable like this:
  762. ```c++
  763. testing::Environment* const foo_env =
  764. testing::AddGlobalTestEnvironment(new FooEnvironment);
  765. ```
  766. However, we strongly recommend you to write your own `main()` and call
  767. `AddGlobalTestEnvironment()` there, as relying on initialization of global
  768. variables makes the code harder to read and may cause problems when you register
  769. multiple environments from different translation units and the environments have
  770. dependencies among them (remember that the compiler doesn't guarantee the order
  771. in which global variables from different translation units are initialized).
  772. ## Value-Parameterized Tests
  773. *Value-parameterized tests* allow you to test your code with different
  774. parameters without writing multiple copies of the same test. This is useful in a
  775. number of situations, for example:
  776. * You have a piece of code whose behavior is affected by one or more
  777. command-line flags. You want to make sure your code performs correctly for
  778. various values of those flags.
  779. * You want to test different implementations of an OO interface.
  780. * You want to test your code over various inputs (a.k.a. data-driven testing).
  781. This feature is easy to abuse, so please exercise your good sense when doing
  782. it!
  783. ### How to Write Value-Parameterized Tests
  784. To write value-parameterized tests, first you should define a fixture class. It
  785. must be derived from both `testing::Test` and `testing::WithParamInterface<T>`
  786. (the latter is a pure interface), where `T` is the type of your parameter
  787. values. For convenience, you can just derive the fixture class from
  788. `testing::TestWithParam<T>`, which itself is derived from both `testing::Test`
  789. and `testing::WithParamInterface<T>`. `T` can be any copyable type. If it's a
  790. raw pointer, you are responsible for managing the lifespan of the pointed
  791. values.
  792. {: .callout .note}
  793. NOTE: If your test fixture defines `SetUpTestSuite()` or `TearDownTestSuite()`
  794. they must be declared **public** rather than **protected** in order to use
  795. `TEST_P`.
  796. ```c++
  797. class FooTest :
  798. public testing::TestWithParam<const char*> {
  799. // You can implement all the usual fixture class members here.
  800. // To access the test parameter, call GetParam() from class
  801. // TestWithParam<T>.
  802. };
  803. // Or, when you want to add parameters to a pre-existing fixture class:
  804. class BaseTest : public testing::Test {
  805. ...
  806. };
  807. class BarTest : public BaseTest,
  808. public testing::WithParamInterface<const char*> {
  809. ...
  810. };
  811. ```
  812. Then, use the `TEST_P` macro to define as many test patterns using this fixture
  813. as you want. The `_P` suffix is for "parameterized" or "pattern", whichever you
  814. prefer to think.
  815. ```c++
  816. TEST_P(FooTest, DoesBlah) {
  817. // Inside a test, access the test parameter with the GetParam() method
  818. // of the TestWithParam<T> class:
  819. EXPECT_TRUE(foo.Blah(GetParam()));
  820. ...
  821. }
  822. TEST_P(FooTest, HasBlahBlah) {
  823. ...
  824. }
  825. ```
  826. Finally, you can use the `INSTANTIATE_TEST_SUITE_P` macro to instantiate the
  827. test suite with any set of parameters you want. GoogleTest defines a number of
  828. functions for generating test parameters—see details at
  829. [`INSTANTIATE_TEST_SUITE_P`](reference/testing.md#INSTANTIATE_TEST_SUITE_P) in
  830. the Testing Reference.
  831. For example, the following statement will instantiate tests from the `FooTest`
  832. test suite each with parameter values `"meeny"`, `"miny"`, and `"moe"` using the
  833. [`Values`](reference/testing.md#param-generators) parameter generator:
  834. ```c++
  835. INSTANTIATE_TEST_SUITE_P(MeenyMinyMoe,
  836. FooTest,
  837. testing::Values("meeny", "miny", "moe"));
  838. ```
  839. {: .callout .note}
  840. NOTE: The code above must be placed at global or namespace scope, not at
  841. function scope.
  842. The first argument to `INSTANTIATE_TEST_SUITE_P` is a unique name for the
  843. instantiation of the test suite. The next argument is the name of the test
  844. pattern, and the last is the
  845. [parameter generator](reference/testing.md#param-generators).
  846. You can instantiate a test pattern more than once, so to distinguish different
  847. instances of the pattern, the instantiation name is added as a prefix to the
  848. actual test suite name. Remember to pick unique prefixes for different
  849. instantiations. The tests from the instantiation above will have these names:
  850. * `MeenyMinyMoe/FooTest.DoesBlah/0` for `"meeny"`
  851. * `MeenyMinyMoe/FooTest.DoesBlah/1` for `"miny"`
  852. * `MeenyMinyMoe/FooTest.DoesBlah/2` for `"moe"`
  853. * `MeenyMinyMoe/FooTest.HasBlahBlah/0` for `"meeny"`
  854. * `MeenyMinyMoe/FooTest.HasBlahBlah/1` for `"miny"`
  855. * `MeenyMinyMoe/FooTest.HasBlahBlah/2` for `"moe"`
  856. You can use these names in [`--gtest_filter`](#running-a-subset-of-the-tests).
  857. The following statement will instantiate all tests from `FooTest` again, each
  858. with parameter values `"cat"` and `"dog"` using the
  859. [`ValuesIn`](reference/testing.md#param-generators) parameter generator:
  860. ```c++
  861. const char* pets[] = {"cat", "dog"};
  862. INSTANTIATE_TEST_SUITE_P(Pets, FooTest, testing::ValuesIn(pets));
  863. ```
  864. The tests from the instantiation above will have these names:
  865. * `Pets/FooTest.DoesBlah/0` for `"cat"`
  866. * `Pets/FooTest.DoesBlah/1` for `"dog"`
  867. * `Pets/FooTest.HasBlahBlah/0` for `"cat"`
  868. * `Pets/FooTest.HasBlahBlah/1` for `"dog"`
  869. Please note that `INSTANTIATE_TEST_SUITE_P` will instantiate *all* tests in the
  870. given test suite, whether their definitions come before or *after* the
  871. `INSTANTIATE_TEST_SUITE_P` statement.
  872. Additionally, by default, every `TEST_P` without a corresponding
  873. `INSTANTIATE_TEST_SUITE_P` causes a failing test in test suite
  874. `GoogleTestVerification`. If you have a test suite where that omission is not an
  875. error, for example it is in a library that may be linked in for other reasons or
  876. where the list of test cases is dynamic and may be empty, then this check can be
  877. suppressed by tagging the test suite:
  878. ```c++
  879. GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(FooTest);
  880. ```
  881. You can see [sample7_unittest.cc] and [sample8_unittest.cc] for more examples.
  882. [sample7_unittest.cc]: https://github.com/google/googletest/blob/master/googletest/samples/sample7_unittest.cc "Parameterized Test example"
  883. [sample8_unittest.cc]: https://github.com/google/googletest/blob/master/googletest/samples/sample8_unittest.cc "Parameterized Test example with multiple parameters"
  884. ### Creating Value-Parameterized Abstract Tests
  885. In the above, we define and instantiate `FooTest` in the *same* source file.
  886. Sometimes you may want to define value-parameterized tests in a library and let
  887. other people instantiate them later. This pattern is known as *abstract tests*.
  888. As an example of its application, when you are designing an interface you can
  889. write a standard suite of abstract tests (perhaps using a factory function as
  890. the test parameter) that all implementations of the interface are expected to
  891. pass. When someone implements the interface, they can instantiate your suite to
  892. get all the interface-conformance tests for free.
  893. To define abstract tests, you should organize your code like this:
  894. 1. Put the definition of the parameterized test fixture class (e.g. `FooTest`)
  895. in a header file, say `foo_param_test.h`. Think of this as *declaring* your
  896. abstract tests.
  897. 2. Put the `TEST_P` definitions in `foo_param_test.cc`, which includes
  898. `foo_param_test.h`. Think of this as *implementing* your abstract tests.
  899. Once they are defined, you can instantiate them by including `foo_param_test.h`,
  900. invoking `INSTANTIATE_TEST_SUITE_P()`, and depending on the library target that
  901. contains `foo_param_test.cc`. You can instantiate the same abstract test suite
  902. multiple times, possibly in different source files.
  903. ### Specifying Names for Value-Parameterized Test Parameters
  904. The optional last argument to `INSTANTIATE_TEST_SUITE_P()` allows the user to
  905. specify a function or functor that generates custom test name suffixes based on
  906. the test parameters. The function should accept one argument of type
  907. `testing::TestParamInfo<class ParamType>`, and return `std::string`.
  908. `testing::PrintToStringParamName` is a builtin test suffix generator that
  909. returns the value of `testing::PrintToString(GetParam())`. It does not work for
  910. `std::string` or C strings.
  911. {: .callout .note}
  912. NOTE: test names must be non-empty, unique, and may only contain ASCII
  913. alphanumeric characters. In particular, they
  914. [should not contain underscores](faq.md#why-should-test-suite-names-and-test-names-not-contain-underscore)
  915. ```c++
  916. class MyTestSuite : public testing::TestWithParam<int> {};
  917. TEST_P(MyTestSuite, MyTest)
  918. {
  919. std::cout << "Example Test Param: " << GetParam() << std::endl;
  920. }
  921. INSTANTIATE_TEST_SUITE_P(MyGroup, MyTestSuite, testing::Range(0, 10),
  922. testing::PrintToStringParamName());
  923. ```
  924. Providing a custom functor allows for more control over test parameter name
  925. generation, especially for types where the automatic conversion does not
  926. generate helpful parameter names (e.g. strings as demonstrated above). The
  927. following example illustrates this for multiple parameters, an enumeration type
  928. and a string, and also demonstrates how to combine generators. It uses a lambda
  929. for conciseness:
  930. ```c++
  931. enum class MyType { MY_FOO = 0, MY_BAR = 1 };
  932. class MyTestSuite : public testing::TestWithParam<std::tuple<MyType, std::string>> {
  933. };
  934. INSTANTIATE_TEST_SUITE_P(
  935. MyGroup, MyTestSuite,
  936. testing::Combine(
  937. testing::Values(MyType::MY_FOO, MyType::MY_BAR),
  938. testing::Values("A", "B")),
  939. [](const testing::TestParamInfo<MyTestSuite::ParamType>& info) {
  940. std::string name = absl::StrCat(
  941. std::get<0>(info.param) == MyType::MY_FOO ? "Foo" : "Bar",
  942. std::get<1>(info.param));
  943. absl::c_replace_if(name, [](char c) { return !std::isalnum(c); }, '_');
  944. return name;
  945. });
  946. ```
  947. ## Typed Tests
  948. Suppose you have multiple implementations of the same interface and want to make
  949. sure that all of them satisfy some common requirements. Or, you may have defined
  950. several types that are supposed to conform to the same "concept" and you want to
  951. verify it. In both cases, you want the same test logic repeated for different
  952. types.
  953. While you can write one `TEST` or `TEST_F` for each type you want to test (and
  954. you may even factor the test logic into a function template that you invoke from
  955. the `TEST`), it's tedious and doesn't scale: if you want `m` tests over `n`
  956. types, you'll end up writing `m*n` `TEST`s.
  957. *Typed tests* allow you to repeat the same test logic over a list of types. You
  958. only need to write the test logic once, although you must know the type list
  959. when writing typed tests. Here's how you do it:
  960. First, define a fixture class template. It should be parameterized by a type.
  961. Remember to derive it from `::testing::Test`:
  962. ```c++
  963. template <typename T>
  964. class FooTest : public testing::Test {
  965. public:
  966. ...
  967. using List = std::list<T>;
  968. static T shared_;
  969. T value_;
  970. };
  971. ```
  972. Next, associate a list of types with the test suite, which will be repeated for
  973. each type in the list:
  974. ```c++
  975. using MyTypes = ::testing::Types<char, int, unsigned int>;
  976. TYPED_TEST_SUITE(FooTest, MyTypes);
  977. ```
  978. The type alias (`using` or `typedef`) is necessary for the `TYPED_TEST_SUITE`
  979. macro to parse correctly. Otherwise the compiler will think that each comma in
  980. the type list introduces a new macro argument.
  981. Then, use `TYPED_TEST()` instead of `TEST_F()` to define a typed test for this
  982. test suite. You can repeat this as many times as you want:
  983. ```c++
  984. TYPED_TEST(FooTest, DoesBlah) {
  985. // Inside a test, refer to the special name TypeParam to get the type
  986. // parameter. Since we are inside a derived class template, C++ requires
  987. // us to visit the members of FooTest via 'this'.
  988. TypeParam n = this->value_;
  989. // To visit static members of the fixture, add the 'TestFixture::'
  990. // prefix.
  991. n += TestFixture::shared_;
  992. // To refer to typedefs in the fixture, add the 'typename TestFixture::'
  993. // prefix. The 'typename' is required to satisfy the compiler.
  994. typename TestFixture::List values;
  995. values.push_back(n);
  996. ...
  997. }
  998. TYPED_TEST(FooTest, HasPropertyA) { ... }
  999. ```
  1000. You can see [sample6_unittest.cc] for a complete example.
  1001. [sample6_unittest.cc]: https://github.com/google/googletest/blob/master/googletest/samples/sample6_unittest.cc "Typed Test example"
  1002. ## Type-Parameterized Tests
  1003. *Type-parameterized tests* are like typed tests, except that they don't require
  1004. you to know the list of types ahead of time. Instead, you can define the test
  1005. logic first and instantiate it with different type lists later. You can even
  1006. instantiate it more than once in the same program.
  1007. If you are designing an interface or concept, you can define a suite of
  1008. type-parameterized tests to verify properties that any valid implementation of
  1009. the interface/concept should have. Then, the author of each implementation can
  1010. just instantiate the test suite with their type to verify that it conforms to
  1011. the requirements, without having to write similar tests repeatedly. Here's an
  1012. example:
  1013. First, define a fixture class template, as we did with typed tests:
  1014. ```c++
  1015. template <typename T>
  1016. class FooTest : public testing::Test {
  1017. ...
  1018. };
  1019. ```
  1020. Next, declare that you will define a type-parameterized test suite:
  1021. ```c++
  1022. TYPED_TEST_SUITE_P(FooTest);
  1023. ```
  1024. Then, use `TYPED_TEST_P()` to define a type-parameterized test. You can repeat
  1025. this as many times as you want:
  1026. ```c++
  1027. TYPED_TEST_P(FooTest, DoesBlah) {
  1028. // Inside a test, refer to TypeParam to get the type parameter.
  1029. TypeParam n = 0;
  1030. ...
  1031. }
  1032. TYPED_TEST_P(FooTest, HasPropertyA) { ... }
  1033. ```
  1034. Now the tricky part: you need to register all test patterns using the
  1035. `REGISTER_TYPED_TEST_SUITE_P` macro before you can instantiate them. The first
  1036. argument of the macro is the test suite name; the rest are the names of the
  1037. tests in this test suite:
  1038. ```c++
  1039. REGISTER_TYPED_TEST_SUITE_P(FooTest,
  1040. DoesBlah, HasPropertyA);
  1041. ```
  1042. Finally, you are free to instantiate the pattern with the types you want. If you
  1043. put the above code in a header file, you can `#include` it in multiple C++
  1044. source files and instantiate it multiple times.
  1045. ```c++
  1046. using MyTypes = ::testing::Types<char, int, unsigned int>;
  1047. INSTANTIATE_TYPED_TEST_SUITE_P(My, FooTest, MyTypes);
  1048. ```
  1049. To distinguish different instances of the pattern, the first argument to the
  1050. `INSTANTIATE_TYPED_TEST_SUITE_P` macro is a prefix that will be added to the
  1051. actual test suite name. Remember to pick unique prefixes for different
  1052. instances.
  1053. In the special case where the type list contains only one type, you can write
  1054. that type directly without `::testing::Types<...>`, like this:
  1055. ```c++
  1056. INSTANTIATE_TYPED_TEST_SUITE_P(My, FooTest, int);
  1057. ```
  1058. You can see [sample6_unittest.cc] for a complete example.
  1059. ## Testing Private Code
  1060. If you change your software's internal implementation, your tests should not
  1061. break as long as the change is not observable by users. Therefore, **per the
  1062. black-box testing principle, most of the time you should test your code through
  1063. its public interfaces.**
  1064. **If you still find yourself needing to test internal implementation code,
  1065. consider if there's a better design.** The desire to test internal
  1066. implementation is often a sign that the class is doing too much. Consider
  1067. extracting an implementation class, and testing it. Then use that implementation
  1068. class in the original class.
  1069. If you absolutely have to test non-public interface code though, you can. There
  1070. are two cases to consider:
  1071. * Static functions ( *not* the same as static member functions!) or unnamed
  1072. namespaces, and
  1073. * Private or protected class members
  1074. To test them, we use the following special techniques:
  1075. * Both static functions and definitions/declarations in an unnamed namespace
  1076. are only visible within the same translation unit. To test them, you can
  1077. `#include` the entire `.cc` file being tested in your `*_test.cc` file.
  1078. (#including `.cc` files is not a good way to reuse code - you should not do
  1079. this in production code!)
  1080. However, a better approach is to move the private code into the
  1081. `foo::internal` namespace, where `foo` is the namespace your project
  1082. normally uses, and put the private declarations in a `*-internal.h` file.
  1083. Your production `.cc` files and your tests are allowed to include this
  1084. internal header, but your clients are not. This way, you can fully test your
  1085. internal implementation without leaking it to your clients.
  1086. * Private class members are only accessible from within the class or by
  1087. friends. To access a class' private members, you can declare your test
  1088. fixture as a friend to the class and define accessors in your fixture. Tests
  1089. using the fixture can then access the private members of your production
  1090. class via the accessors in the fixture. Note that even though your fixture
  1091. is a friend to your production class, your tests are not automatically
  1092. friends to it, as they are technically defined in sub-classes of the
  1093. fixture.
  1094. Another way to test private members is to refactor them into an
  1095. implementation class, which is then declared in a `*-internal.h` file. Your
  1096. clients aren't allowed to include this header but your tests can. Such is
  1097. called the
  1098. [Pimpl](https://www.gamedev.net/articles/programming/general-and-gameplay-programming/the-c-pimpl-r1794/)
  1099. (Private Implementation) idiom.
  1100. Or, you can declare an individual test as a friend of your class by adding
  1101. this line in the class body:
  1102. ```c++
  1103. FRIEND_TEST(TestSuiteName, TestName);
  1104. ```
  1105. For example,
  1106. ```c++
  1107. // foo.h
  1108. class Foo {
  1109. ...
  1110. private:
  1111. FRIEND_TEST(FooTest, BarReturnsZeroOnNull);
  1112. int Bar(void* x);
  1113. };
  1114. // foo_test.cc
  1115. ...
  1116. TEST(FooTest, BarReturnsZeroOnNull) {
  1117. Foo foo;
  1118. EXPECT_EQ(foo.Bar(NULL), 0); // Uses Foo's private member Bar().
  1119. }
  1120. ```
  1121. Pay special attention when your class is defined in a namespace. If you want
  1122. your test fixtures and tests to be friends of your class, then they must be
  1123. defined in the exact same namespace (no anonymous or inline namespaces).
  1124. For example, if the code to be tested looks like:
  1125. ```c++
  1126. namespace my_namespace {
  1127. class Foo {
  1128. friend class FooTest;
  1129. FRIEND_TEST(FooTest, Bar);
  1130. FRIEND_TEST(FooTest, Baz);
  1131. ... definition of the class Foo ...
  1132. };
  1133. } // namespace my_namespace
  1134. ```
  1135. Your test code should be something like:
  1136. ```c++
  1137. namespace my_namespace {
  1138. class FooTest : public testing::Test {
  1139. protected:
  1140. ...
  1141. };
  1142. TEST_F(FooTest, Bar) { ... }
  1143. TEST_F(FooTest, Baz) { ... }
  1144. } // namespace my_namespace
  1145. ```
  1146. ## "Catching" Failures
  1147. If you are building a testing utility on top of googletest, you'll want to test
  1148. your utility. What framework would you use to test it? googletest, of course.
  1149. The challenge is to verify that your testing utility reports failures correctly.
  1150. In frameworks that report a failure by throwing an exception, you could catch
  1151. the exception and assert on it. But googletest doesn't use exceptions, so how do
  1152. we test that a piece of code generates an expected failure?
  1153. `"gtest/gtest-spi.h"` contains some constructs to do this. After #including this header,
  1154. you can use
  1155. ```c++
  1156. EXPECT_FATAL_FAILURE(statement, substring);
  1157. ```
  1158. to assert that `statement` generates a fatal (e.g. `ASSERT_*`) failure in the
  1159. current thread whose message contains the given `substring`, or use
  1160. ```c++
  1161. EXPECT_NONFATAL_FAILURE(statement, substring);
  1162. ```
  1163. if you are expecting a non-fatal (e.g. `EXPECT_*`) failure.
  1164. Only failures in the current thread are checked to determine the result of this
  1165. type of expectations. If `statement` creates new threads, failures in these
  1166. threads are also ignored. If you want to catch failures in other threads as
  1167. well, use one of the following macros instead:
  1168. ```c++
  1169. EXPECT_FATAL_FAILURE_ON_ALL_THREADS(statement, substring);
  1170. EXPECT_NONFATAL_FAILURE_ON_ALL_THREADS(statement, substring);
  1171. ```
  1172. {: .callout .note}
  1173. NOTE: Assertions from multiple threads are currently not supported on Windows.
  1174. For technical reasons, there are some caveats:
  1175. 1. You cannot stream a failure message to either macro.
  1176. 2. `statement` in `EXPECT_FATAL_FAILURE{_ON_ALL_THREADS}()` cannot reference
  1177. local non-static variables or non-static members of `this` object.
  1178. 3. `statement` in `EXPECT_FATAL_FAILURE{_ON_ALL_THREADS}()` cannot return a
  1179. value.
  1180. ## Registering tests programmatically
  1181. The `TEST` macros handle the vast majority of all use cases, but there are few
  1182. where runtime registration logic is required. For those cases, the framework
  1183. provides the `::testing::RegisterTest` that allows callers to register arbitrary
  1184. tests dynamically.
  1185. This is an advanced API only to be used when the `TEST` macros are insufficient.
  1186. The macros should be preferred when possible, as they avoid most of the
  1187. complexity of calling this function.
  1188. It provides the following signature:
  1189. ```c++
  1190. template <typename Factory>
  1191. TestInfo* RegisterTest(const char* test_suite_name, const char* test_name,
  1192. const char* type_param, const char* value_param,
  1193. const char* file, int line, Factory factory);
  1194. ```
  1195. The `factory` argument is a factory callable (move-constructible) object or
  1196. function pointer that creates a new instance of the Test object. It handles
  1197. ownership to the caller. The signature of the callable is `Fixture*()`, where
  1198. `Fixture` is the test fixture class for the test. All tests registered with the
  1199. same `test_suite_name` must return the same fixture type. This is checked at
  1200. runtime.
  1201. The framework will infer the fixture class from the factory and will call the
  1202. `SetUpTestSuite` and `TearDownTestSuite` for it.
  1203. Must be called before `RUN_ALL_TESTS()` is invoked, otherwise behavior is
  1204. undefined.
  1205. Use case example:
  1206. ```c++
  1207. class MyFixture : public testing::Test {
  1208. public:
  1209. // All of these optional, just like in regular macro usage.
  1210. static void SetUpTestSuite() { ... }
  1211. static void TearDownTestSuite() { ... }
  1212. void SetUp() override { ... }
  1213. void TearDown() override { ... }
  1214. };
  1215. class MyTest : public MyFixture {
  1216. public:
  1217. explicit MyTest(int data) : data_(data) {}
  1218. void TestBody() override { ... }
  1219. private:
  1220. int data_;
  1221. };
  1222. void RegisterMyTests(const std::vector<int>& values) {
  1223. for (int v : values) {
  1224. testing::RegisterTest(
  1225. "MyFixture", ("Test" + std::to_string(v)).c_str(), nullptr,
  1226. std::to_string(v).c_str(),
  1227. __FILE__, __LINE__,
  1228. // Important to use the fixture type as the return type here.
  1229. [=]() -> MyFixture* { return new MyTest(v); });
  1230. }
  1231. }
  1232. ...
  1233. int main(int argc, char** argv) {
  1234. std::vector<int> values_to_test = LoadValuesFromConfig();
  1235. RegisterMyTests(values_to_test);
  1236. ...
  1237. return RUN_ALL_TESTS();
  1238. }
  1239. ```
  1240. ## Getting the Current Test's Name
  1241. Sometimes a function may need to know the name of the currently running test.
  1242. For example, you may be using the `SetUp()` method of your test fixture to set
  1243. the golden file name based on which test is running. The
  1244. [`TestInfo`](reference/testing.md#TestInfo) class has this information.
  1245. To obtain a `TestInfo` object for the currently running test, call
  1246. `current_test_info()` on the [`UnitTest`](reference/testing.md#UnitTest)
  1247. singleton object:
  1248. ```c++
  1249. // Gets information about the currently running test.
  1250. // Do NOT delete the returned object - it's managed by the UnitTest class.
  1251. const testing::TestInfo* const test_info =
  1252. testing::UnitTest::GetInstance()->current_test_info();
  1253. printf("We are in test %s of test suite %s.\n",
  1254. test_info->name(),
  1255. test_info->test_suite_name());
  1256. ```
  1257. `current_test_info()` returns a null pointer if no test is running. In
  1258. particular, you cannot find the test suite name in `SetUpTestSuite()`,
  1259. `TearDownTestSuite()` (where you know the test suite name implicitly), or
  1260. functions called from them.
  1261. ## Extending googletest by Handling Test Events
  1262. googletest provides an **event listener API** to let you receive notifications
  1263. about the progress of a test program and test failures. The events you can
  1264. listen to include the start and end of the test program, a test suite, or a test
  1265. method, among others. You may use this API to augment or replace the standard
  1266. console output, replace the XML output, or provide a completely different form
  1267. of output, such as a GUI or a database. You can also use test events as
  1268. checkpoints to implement a resource leak checker, for example.
  1269. ### Defining Event Listeners
  1270. To define a event listener, you subclass either
  1271. [`testing::TestEventListener`](reference/testing.md#TestEventListener) or
  1272. [`testing::EmptyTestEventListener`](reference/testing.md#EmptyTestEventListener)
  1273. The former is an (abstract) interface, where *each pure virtual method can be
  1274. overridden to handle a test event* (For example, when a test starts, the
  1275. `OnTestStart()` method will be called.). The latter provides an empty
  1276. implementation of all methods in the interface, such that a subclass only needs
  1277. to override the methods it cares about.
  1278. When an event is fired, its context is passed to the handler function as an
  1279. argument. The following argument types are used:
  1280. * UnitTest reflects the state of the entire test program,
  1281. * TestSuite has information about a test suite, which can contain one or more
  1282. tests,
  1283. * TestInfo contains the state of a test, and
  1284. * TestPartResult represents the result of a test assertion.
  1285. An event handler function can examine the argument it receives to find out
  1286. interesting information about the event and the test program's state.
  1287. Here's an example:
  1288. ```c++
  1289. class MinimalistPrinter : public testing::EmptyTestEventListener {
  1290. // Called before a test starts.
  1291. void OnTestStart(const testing::TestInfo& test_info) override {
  1292. printf("*** Test %s.%s starting.\n",
  1293. test_info.test_suite_name(), test_info.name());
  1294. }
  1295. // Called after a failed assertion or a SUCCESS().
  1296. void OnTestPartResult(const testing::TestPartResult& test_part_result) override {
  1297. printf("%s in %s:%d\n%s\n",
  1298. test_part_result.failed() ? "*** Failure" : "Success",
  1299. test_part_result.file_name(),
  1300. test_part_result.line_number(),
  1301. test_part_result.summary());
  1302. }
  1303. // Called after a test ends.
  1304. void OnTestEnd(const testing::TestInfo& test_info) override {
  1305. printf("*** Test %s.%s ending.\n",
  1306. test_info.test_suite_name(), test_info.name());
  1307. }
  1308. };
  1309. ```
  1310. ### Using Event Listeners
  1311. To use the event listener you have defined, add an instance of it to the
  1312. googletest event listener list (represented by class
  1313. [`TestEventListeners`](reference/testing.md#TestEventListeners) - note the "s"
  1314. at the end of the name) in your `main()` function, before calling
  1315. `RUN_ALL_TESTS()`:
  1316. ```c++
  1317. int main(int argc, char** argv) {
  1318. testing::InitGoogleTest(&argc, argv);
  1319. // Gets hold of the event listener list.
  1320. testing::TestEventListeners& listeners =
  1321. testing::UnitTest::GetInstance()->listeners();
  1322. // Adds a listener to the end. googletest takes the ownership.
  1323. listeners.Append(new MinimalistPrinter);
  1324. return RUN_ALL_TESTS();
  1325. }
  1326. ```
  1327. There's only one problem: the default test result printer is still in effect, so
  1328. its output will mingle with the output from your minimalist printer. To suppress
  1329. the default printer, just release it from the event listener list and delete it.
  1330. You can do so by adding one line:
  1331. ```c++
  1332. ...
  1333. delete listeners.Release(listeners.default_result_printer());
  1334. listeners.Append(new MinimalistPrinter);
  1335. return RUN_ALL_TESTS();
  1336. ```
  1337. Now, sit back and enjoy a completely different output from your tests. For more
  1338. details, see [sample9_unittest.cc].
  1339. [sample9_unittest.cc]: https://github.com/google/googletest/blob/master/googletest/samples/sample9_unittest.cc "Event listener example"
  1340. You may append more than one listener to the list. When an `On*Start()` or
  1341. `OnTestPartResult()` event is fired, the listeners will receive it in the order
  1342. they appear in the list (since new listeners are added to the end of the list,
  1343. the default text printer and the default XML generator will receive the event
  1344. first). An `On*End()` event will be received by the listeners in the *reverse*
  1345. order. This allows output by listeners added later to be framed by output from
  1346. listeners added earlier.
  1347. ### Generating Failures in Listeners
  1348. You may use failure-raising macros (`EXPECT_*()`, `ASSERT_*()`, `FAIL()`, etc)
  1349. when processing an event. There are some restrictions:
  1350. 1. You cannot generate any failure in `OnTestPartResult()` (otherwise it will
  1351. cause `OnTestPartResult()` to be called recursively).
  1352. 2. A listener that handles `OnTestPartResult()` is not allowed to generate any
  1353. failure.
  1354. When you add listeners to the listener list, you should put listeners that
  1355. handle `OnTestPartResult()` *before* listeners that can generate failures. This
  1356. ensures that failures generated by the latter are attributed to the right test
  1357. by the former.
  1358. See [sample10_unittest.cc] for an example of a failure-raising listener.
  1359. [sample10_unittest.cc]: https://github.com/google/googletest/blob/master/googletest/samples/sample10_unittest.cc "Failure-raising listener example"
  1360. ## Running Test Programs: Advanced Options
  1361. googletest test programs are ordinary executables. Once built, you can run them
  1362. directly and affect their behavior via the following environment variables
  1363. and/or command line flags. For the flags to work, your programs must call
  1364. `::testing::InitGoogleTest()` before calling `RUN_ALL_TESTS()`.
  1365. To see a list of supported flags and their usage, please run your test program
  1366. with the `--help` flag. You can also use `-h`, `-?`, or `/?` for short.
  1367. If an option is specified both by an environment variable and by a flag, the
  1368. latter takes precedence.
  1369. ### Selecting Tests
  1370. #### Listing Test Names
  1371. Sometimes it is necessary to list the available tests in a program before
  1372. running them so that a filter may be applied if needed. Including the flag
  1373. `--gtest_list_tests` overrides all other flags and lists tests in the following
  1374. format:
  1375. ```none
  1376. TestSuite1.
  1377. TestName1
  1378. TestName2
  1379. TestSuite2.
  1380. TestName
  1381. ```
  1382. None of the tests listed are actually run if the flag is provided. There is no
  1383. corresponding environment variable for this flag.
  1384. #### Running a Subset of the Tests
  1385. By default, a googletest program runs all tests the user has defined. Sometimes,
  1386. you want to run only a subset of the tests (e.g. for debugging or quickly
  1387. verifying a change). If you set the `GTEST_FILTER` environment variable or the
  1388. `--gtest_filter` flag to a filter string, googletest will only run the tests
  1389. whose full names (in the form of `TestSuiteName.TestName`) match the filter.
  1390. The format of a filter is a '`:`'-separated list of wildcard patterns (called
  1391. the *positive patterns*) optionally followed by a '`-`' and another
  1392. '`:`'-separated pattern list (called the *negative patterns*). A test matches
  1393. the filter if and only if it matches any of the positive patterns but does not
  1394. match any of the negative patterns.
  1395. A pattern may contain `'*'` (matches any string) or `'?'` (matches any single
  1396. character). For convenience, the filter `'*-NegativePatterns'` can be also
  1397. written as `'-NegativePatterns'`.
  1398. For example:
  1399. * `./foo_test` Has no flag, and thus runs all its tests.
  1400. * `./foo_test --gtest_filter=*` Also runs everything, due to the single
  1401. match-everything `*` value.
  1402. * `./foo_test --gtest_filter=FooTest.*` Runs everything in test suite
  1403. `FooTest` .
  1404. * `./foo_test --gtest_filter=*Null*:*Constructor*` Runs any test whose full
  1405. name contains either `"Null"` or `"Constructor"` .
  1406. * `./foo_test --gtest_filter=-*DeathTest.*` Runs all non-death tests.
  1407. * `./foo_test --gtest_filter=FooTest.*-FooTest.Bar` Runs everything in test
  1408. suite `FooTest` except `FooTest.Bar`.
  1409. * `./foo_test --gtest_filter=FooTest.*:BarTest.*-FooTest.Bar:BarTest.Foo` Runs
  1410. everything in test suite `FooTest` except `FooTest.Bar` and everything in
  1411. test suite `BarTest` except `BarTest.Foo`.
  1412. #### Stop test execution upon first failure
  1413. By default, a googletest program runs all tests the user has defined. In some
  1414. cases (e.g. iterative test development & execution) it may be desirable stop
  1415. test execution upon first failure (trading improved latency for completeness).
  1416. If `GTEST_FAIL_FAST` environment variable or `--gtest_fail_fast` flag is set,
  1417. the test runner will stop execution as soon as the first test failure is
  1418. found.
  1419. #### Temporarily Disabling Tests
  1420. If you have a broken test that you cannot fix right away, you can add the
  1421. `DISABLED_` prefix to its name. This will exclude it from execution. This is
  1422. better than commenting out the code or using `#if 0`, as disabled tests are
  1423. still compiled (and thus won't rot).
  1424. If you need to disable all tests in a test suite, you can either add `DISABLED_`
  1425. to the front of the name of each test, or alternatively add it to the front of
  1426. the test suite name.
  1427. For example, the following tests won't be run by googletest, even though they
  1428. will still be compiled:
  1429. ```c++
  1430. // Tests that Foo does Abc.
  1431. TEST(FooTest, DISABLED_DoesAbc) { ... }
  1432. class DISABLED_BarTest : public testing::Test { ... };
  1433. // Tests that Bar does Xyz.
  1434. TEST_F(DISABLED_BarTest, DoesXyz) { ... }
  1435. ```
  1436. {: .callout .note}
  1437. NOTE: This feature should only be used for temporary pain-relief. You still have
  1438. to fix the disabled tests at a later date. As a reminder, googletest will print
  1439. a banner warning you if a test program contains any disabled tests.
  1440. {: .callout .tip}
  1441. TIP: You can easily count the number of disabled tests you have using
  1442. `grep`. This number can be used as a metric for
  1443. improving your test quality.
  1444. #### Temporarily Enabling Disabled Tests
  1445. To include disabled tests in test execution, just invoke the test program with
  1446. the `--gtest_also_run_disabled_tests` flag or set the
  1447. `GTEST_ALSO_RUN_DISABLED_TESTS` environment variable to a value other than `0`.
  1448. You can combine this with the `--gtest_filter` flag to further select which
  1449. disabled tests to run.
  1450. ### Repeating the Tests
  1451. Once in a while you'll run into a test whose result is hit-or-miss. Perhaps it
  1452. will fail only 1% of the time, making it rather hard to reproduce the bug under
  1453. a debugger. This can be a major source of frustration.
  1454. The `--gtest_repeat` flag allows you to repeat all (or selected) test methods in
  1455. a program many times. Hopefully, a flaky test will eventually fail and give you
  1456. a chance to debug. Here's how to use it:
  1457. ```none
  1458. $ foo_test --gtest_repeat=1000
  1459. Repeat foo_test 1000 times and don't stop at failures.
  1460. $ foo_test --gtest_repeat=-1
  1461. A negative count means repeating forever.
  1462. $ foo_test --gtest_repeat=1000 --gtest_break_on_failure
  1463. Repeat foo_test 1000 times, stopping at the first failure. This
  1464. is especially useful when running under a debugger: when the test
  1465. fails, it will drop into the debugger and you can then inspect
  1466. variables and stacks.
  1467. $ foo_test --gtest_repeat=1000 --gtest_filter=FooBar.*
  1468. Repeat the tests whose name matches the filter 1000 times.
  1469. ```
  1470. If your test program contains
  1471. [global set-up/tear-down](#global-set-up-and-tear-down) code, it will be
  1472. repeated in each iteration as well, as the flakiness may be in it. You can also
  1473. specify the repeat count by setting the `GTEST_REPEAT` environment variable.
  1474. ### Shuffling the Tests
  1475. You can specify the `--gtest_shuffle` flag (or set the `GTEST_SHUFFLE`
  1476. environment variable to `1`) to run the tests in a program in a random order.
  1477. This helps to reveal bad dependencies between tests.
  1478. By default, googletest uses a random seed calculated from the current time.
  1479. Therefore you'll get a different order every time. The console output includes
  1480. the random seed value, such that you can reproduce an order-related test failure
  1481. later. To specify the random seed explicitly, use the `--gtest_random_seed=SEED`
  1482. flag (or set the `GTEST_RANDOM_SEED` environment variable), where `SEED` is an
  1483. integer in the range [0, 99999]. The seed value 0 is special: it tells
  1484. googletest to do the default behavior of calculating the seed from the current
  1485. time.
  1486. If you combine this with `--gtest_repeat=N`, googletest will pick a different
  1487. random seed and re-shuffle the tests in each iteration.
  1488. ### Controlling Test Output
  1489. #### Colored Terminal Output
  1490. googletest can use colors in its terminal output to make it easier to spot the
  1491. important information:
  1492. <pre>...
  1493. <font color="green">[----------]</font> 1 test from FooTest
  1494. <font color="green">[ RUN ]</font> FooTest.DoesAbc
  1495. <font color="green">[ OK ]</font> FooTest.DoesAbc
  1496. <font color="green">[----------]</font> 2 tests from BarTest
  1497. <font color="green">[ RUN ]</font> BarTest.HasXyzProperty
  1498. <font color="green">[ OK ]</font> BarTest.HasXyzProperty
  1499. <font color="green">[ RUN ]</font> BarTest.ReturnsTrueOnSuccess
  1500. ... some error messages ...
  1501. <font color="red">[ FAILED ]</font> BarTest.ReturnsTrueOnSuccess
  1502. ...
  1503. <font color="green">[==========]</font> 30 tests from 14 test suites ran.
  1504. <font color="green">[ PASSED ]</font> 28 tests.
  1505. <font color="red">[ FAILED ]</font> 2 tests, listed below:
  1506. <font color="red">[ FAILED ]</font> BarTest.ReturnsTrueOnSuccess
  1507. <font color="red">[ FAILED ]</font> AnotherTest.DoesXyz
  1508. 2 FAILED TESTS
  1509. </pre>
  1510. You can set the `GTEST_COLOR` environment variable or the `--gtest_color`
  1511. command line flag to `yes`, `no`, or `auto` (the default) to enable colors,
  1512. disable colors, or let googletest decide. When the value is `auto`, googletest
  1513. will use colors if and only if the output goes to a terminal and (on non-Windows
  1514. platforms) the `TERM` environment variable is set to `xterm` or `xterm-color`.
  1515. #### Suppressing test passes
  1516. By default, googletest prints 1 line of output for each test, indicating if it
  1517. passed or failed. To show only test failures, run the test program with
  1518. `--gtest_brief=1`, or set the GTEST_BRIEF environment variable to `1`.
  1519. #### Suppressing the Elapsed Time
  1520. By default, googletest prints the time it takes to run each test. To disable
  1521. that, run the test program with the `--gtest_print_time=0` command line flag, or
  1522. set the GTEST_PRINT_TIME environment variable to `0`.
  1523. #### Suppressing UTF-8 Text Output
  1524. In case of assertion failures, googletest prints expected and actual values of
  1525. type `string` both as hex-encoded strings as well as in readable UTF-8 text if
  1526. they contain valid non-ASCII UTF-8 characters. If you want to suppress the UTF-8
  1527. text because, for example, you don't have an UTF-8 compatible output medium, run
  1528. the test program with `--gtest_print_utf8=0` or set the `GTEST_PRINT_UTF8`
  1529. environment variable to `0`.
  1530. #### Generating an XML Report
  1531. googletest can emit a detailed XML report to a file in addition to its normal
  1532. textual output. The report contains the duration of each test, and thus can help
  1533. you identify slow tests.
  1534. To generate the XML report, set the `GTEST_OUTPUT` environment variable or the
  1535. `--gtest_output` flag to the string `"xml:path_to_output_file"`, which will
  1536. create the file at the given location. You can also just use the string `"xml"`,
  1537. in which case the output can be found in the `test_detail.xml` file in the
  1538. current directory.
  1539. If you specify a directory (for example, `"xml:output/directory/"` on Linux or
  1540. `"xml:output\directory\"` on Windows), googletest will create the XML file in
  1541. that directory, named after the test executable (e.g. `foo_test.xml` for test
  1542. program `foo_test` or `foo_test.exe`). If the file already exists (perhaps left
  1543. over from a previous run), googletest will pick a different name (e.g.
  1544. `foo_test_1.xml`) to avoid overwriting it.
  1545. The report is based on the `junitreport` Ant task. Since that format was
  1546. originally intended for Java, a little interpretation is required to make it
  1547. apply to googletest tests, as shown here:
  1548. ```xml
  1549. <testsuites name="AllTests" ...>
  1550. <testsuite name="test_case_name" ...>
  1551. <testcase name="test_name" ...>
  1552. <failure message="..."/>
  1553. <failure message="..."/>
  1554. <failure message="..."/>
  1555. </testcase>
  1556. </testsuite>
  1557. </testsuites>
  1558. ```
  1559. * The root `<testsuites>` element corresponds to the entire test program.
  1560. * `<testsuite>` elements correspond to googletest test suites.
  1561. * `<testcase>` elements correspond to googletest test functions.
  1562. For instance, the following program
  1563. ```c++
  1564. TEST(MathTest, Addition) { ... }
  1565. TEST(MathTest, Subtraction) { ... }
  1566. TEST(LogicTest, NonContradiction) { ... }
  1567. ```
  1568. could generate this report:
  1569. ```xml
  1570. <?xml version="1.0" encoding="UTF-8"?>
  1571. <testsuites tests="3" failures="1" errors="0" time="0.035" timestamp="2011-10-31T18:52:42" name="AllTests">
  1572. <testsuite name="MathTest" tests="2" failures="1" errors="0" time="0.015">
  1573. <testcase name="Addition" status="run" time="0.007" classname="">
  1574. <failure message="Value of: add(1, 1)&#x0A; Actual: 3&#x0A;Expected: 2" type="">...</failure>
  1575. <failure message="Value of: add(1, -1)&#x0A; Actual: 1&#x0A;Expected: 0" type="">...</failure>
  1576. </testcase>
  1577. <testcase name="Subtraction" status="run" time="0.005" classname="">
  1578. </testcase>
  1579. </testsuite>
  1580. <testsuite name="LogicTest" tests="1" failures="0" errors="0" time="0.005">
  1581. <testcase name="NonContradiction" status="run" time="0.005" classname="">
  1582. </testcase>
  1583. </testsuite>
  1584. </testsuites>
  1585. ```
  1586. Things to note:
  1587. * The `tests` attribute of a `<testsuites>` or `<testsuite>` element tells how
  1588. many test functions the googletest program or test suite contains, while the
  1589. `failures` attribute tells how many of them failed.
  1590. * The `time` attribute expresses the duration of the test, test suite, or
  1591. entire test program in seconds.
  1592. * The `timestamp` attribute records the local date and time of the test
  1593. execution.
  1594. * Each `<failure>` element corresponds to a single failed googletest
  1595. assertion.
  1596. #### Generating a JSON Report
  1597. googletest can also emit a JSON report as an alternative format to XML. To
  1598. generate the JSON report, set the `GTEST_OUTPUT` environment variable or the
  1599. `--gtest_output` flag to the string `"json:path_to_output_file"`, which will
  1600. create the file at the given location. You can also just use the string
  1601. `"json"`, in which case the output can be found in the `test_detail.json` file
  1602. in the current directory.
  1603. The report format conforms to the following JSON Schema:
  1604. ```json
  1605. {
  1606. "$schema": "http://json-schema.org/schema#",
  1607. "type": "object",
  1608. "definitions": {
  1609. "TestCase": {
  1610. "type": "object",
  1611. "properties": {
  1612. "name": { "type": "string" },
  1613. "tests": { "type": "integer" },
  1614. "failures": { "type": "integer" },
  1615. "disabled": { "type": "integer" },
  1616. "time": { "type": "string" },
  1617. "testsuite": {
  1618. "type": "array",
  1619. "items": {
  1620. "$ref": "#/definitions/TestInfo"
  1621. }
  1622. }
  1623. }
  1624. },
  1625. "TestInfo": {
  1626. "type": "object",
  1627. "properties": {
  1628. "name": { "type": "string" },
  1629. "status": {
  1630. "type": "string",
  1631. "enum": ["RUN", "NOTRUN"]
  1632. },
  1633. "time": { "type": "string" },
  1634. "classname": { "type": "string" },
  1635. "failures": {
  1636. "type": "array",
  1637. "items": {
  1638. "$ref": "#/definitions/Failure"
  1639. }
  1640. }
  1641. }
  1642. },
  1643. "Failure": {
  1644. "type": "object",
  1645. "properties": {
  1646. "failures": { "type": "string" },
  1647. "type": { "type": "string" }
  1648. }
  1649. }
  1650. },
  1651. "properties": {
  1652. "tests": { "type": "integer" },
  1653. "failures": { "type": "integer" },
  1654. "disabled": { "type": "integer" },
  1655. "errors": { "type": "integer" },
  1656. "timestamp": {
  1657. "type": "string",
  1658. "format": "date-time"
  1659. },
  1660. "time": { "type": "string" },
  1661. "name": { "type": "string" },
  1662. "testsuites": {
  1663. "type": "array",
  1664. "items": {
  1665. "$ref": "#/definitions/TestCase"
  1666. }
  1667. }
  1668. }
  1669. }
  1670. ```
  1671. The report uses the format that conforms to the following Proto3 using the
  1672. [JSON encoding](https://developers.google.com/protocol-buffers/docs/proto3#json):
  1673. ```proto
  1674. syntax = "proto3";
  1675. package googletest;
  1676. import "google/protobuf/timestamp.proto";
  1677. import "google/protobuf/duration.proto";
  1678. message UnitTest {
  1679. int32 tests = 1;
  1680. int32 failures = 2;
  1681. int32 disabled = 3;
  1682. int32 errors = 4;
  1683. google.protobuf.Timestamp timestamp = 5;
  1684. google.protobuf.Duration time = 6;
  1685. string name = 7;
  1686. repeated TestCase testsuites = 8;
  1687. }
  1688. message TestCase {
  1689. string name = 1;
  1690. int32 tests = 2;
  1691. int32 failures = 3;
  1692. int32 disabled = 4;
  1693. int32 errors = 5;
  1694. google.protobuf.Duration time = 6;
  1695. repeated TestInfo testsuite = 7;
  1696. }
  1697. message TestInfo {
  1698. string name = 1;
  1699. enum Status {
  1700. RUN = 0;
  1701. NOTRUN = 1;
  1702. }
  1703. Status status = 2;
  1704. google.protobuf.Duration time = 3;
  1705. string classname = 4;
  1706. message Failure {
  1707. string failures = 1;
  1708. string type = 2;
  1709. }
  1710. repeated Failure failures = 5;
  1711. }
  1712. ```
  1713. For instance, the following program
  1714. ```c++
  1715. TEST(MathTest, Addition) { ... }
  1716. TEST(MathTest, Subtraction) { ... }
  1717. TEST(LogicTest, NonContradiction) { ... }
  1718. ```
  1719. could generate this report:
  1720. ```json
  1721. {
  1722. "tests": 3,
  1723. "failures": 1,
  1724. "errors": 0,
  1725. "time": "0.035s",
  1726. "timestamp": "2011-10-31T18:52:42Z",
  1727. "name": "AllTests",
  1728. "testsuites": [
  1729. {
  1730. "name": "MathTest",
  1731. "tests": 2,
  1732. "failures": 1,
  1733. "errors": 0,
  1734. "time": "0.015s",
  1735. "testsuite": [
  1736. {
  1737. "name": "Addition",
  1738. "status": "RUN",
  1739. "time": "0.007s",
  1740. "classname": "",
  1741. "failures": [
  1742. {
  1743. "message": "Value of: add(1, 1)\n Actual: 3\nExpected: 2",
  1744. "type": ""
  1745. },
  1746. {
  1747. "message": "Value of: add(1, -1)\n Actual: 1\nExpected: 0",
  1748. "type": ""
  1749. }
  1750. ]
  1751. },
  1752. {
  1753. "name": "Subtraction",
  1754. "status": "RUN",
  1755. "time": "0.005s",
  1756. "classname": ""
  1757. }
  1758. ]
  1759. },
  1760. {
  1761. "name": "LogicTest",
  1762. "tests": 1,
  1763. "failures": 0,
  1764. "errors": 0,
  1765. "time": "0.005s",
  1766. "testsuite": [
  1767. {
  1768. "name": "NonContradiction",
  1769. "status": "RUN",
  1770. "time": "0.005s",
  1771. "classname": ""
  1772. }
  1773. ]
  1774. }
  1775. ]
  1776. }
  1777. ```
  1778. {: .callout .important}
  1779. IMPORTANT: The exact format of the JSON document is subject to change.
  1780. ### Controlling How Failures Are Reported
  1781. #### Detecting Test Premature Exit
  1782. Google Test implements the _premature-exit-file_ protocol for test runners
  1783. to catch any kind of unexpected exits of test programs. Upon start,
  1784. Google Test creates the file which will be automatically deleted after
  1785. all work has been finished. Then, the test runner can check if this file
  1786. exists. In case the file remains undeleted, the inspected test has exited
  1787. prematurely.
  1788. This feature is enabled only if the `TEST_PREMATURE_EXIT_FILE` environment
  1789. variable has been set.
  1790. #### Turning Assertion Failures into Break-Points
  1791. When running test programs under a debugger, it's very convenient if the
  1792. debugger can catch an assertion failure and automatically drop into interactive
  1793. mode. googletest's *break-on-failure* mode supports this behavior.
  1794. To enable it, set the `GTEST_BREAK_ON_FAILURE` environment variable to a value
  1795. other than `0`. Alternatively, you can use the `--gtest_break_on_failure`
  1796. command line flag.
  1797. #### Disabling Catching Test-Thrown Exceptions
  1798. googletest can be used either with or without exceptions enabled. If a test
  1799. throws a C++ exception or (on Windows) a structured exception (SEH), by default
  1800. googletest catches it, reports it as a test failure, and continues with the next
  1801. test method. This maximizes the coverage of a test run. Also, on Windows an
  1802. uncaught exception will cause a pop-up window, so catching the exceptions allows
  1803. you to run the tests automatically.
  1804. When debugging the test failures, however, you may instead want the exceptions
  1805. to be handled by the debugger, such that you can examine the call stack when an
  1806. exception is thrown. To achieve that, set the `GTEST_CATCH_EXCEPTIONS`
  1807. environment variable to `0`, or use the `--gtest_catch_exceptions=0` flag when
  1808. running the tests.
  1809. ### Sanitizer Integration
  1810. The
  1811. [Undefined Behavior Sanitizer](https://clang.llvm.org/docs/UndefinedBehaviorSanitizer.html),
  1812. [Address Sanitizer](https://github.com/google/sanitizers/wiki/AddressSanitizer),
  1813. and
  1814. [Thread Sanitizer](https://github.com/google/sanitizers/wiki/ThreadSanitizerCppManual)
  1815. all provide weak functions that you can override to trigger explicit failures
  1816. when they detect sanitizer errors, such as creating a reference from `nullptr`.
  1817. To override these functions, place definitions for them in a source file that
  1818. you compile as part of your main binary:
  1819. ```
  1820. extern "C" {
  1821. void __ubsan_on_report() {
  1822. FAIL() << "Encountered an undefined behavior sanitizer error";
  1823. }
  1824. void __asan_on_error() {
  1825. FAIL() << "Encountered an address sanitizer error";
  1826. }
  1827. void __tsan_on_report() {
  1828. FAIL() << "Encountered a thread sanitizer error";
  1829. }
  1830. } // extern "C"
  1831. ```
  1832. After compiling your project with one of the sanitizers enabled, if a particular
  1833. test triggers a sanitizer error, googletest will report that it failed.