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2446 lines
87 KiB
2446 lines
87 KiB
# Advanced GoogleTest Topics |
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## Introduction |
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Now that you have read the [GoogleTest Primer](primer.md) and learned how to |
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write tests using GoogleTest, it's time to learn some new tricks. This document |
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will show you more assertions as well as how to construct complex failure |
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messages, propagate fatal failures, reuse and speed up your test fixtures, and |
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use various flags with your tests. |
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## More Assertions |
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This section covers some less frequently used, but still significant, |
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assertions. |
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### Explicit Success and Failure |
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See [Explicit Success and Failure](reference/assertions.md#success-failure) in |
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the Assertions Reference. |
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### Exception Assertions |
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See [Exception Assertions](reference/assertions.md#exceptions) in the Assertions |
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Reference. |
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### Predicate Assertions for Better Error Messages |
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Even though GoogleTest has a rich set of assertions, they can never be complete, |
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as it's impossible (nor a good idea) to anticipate all scenarios a user might |
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run into. Therefore, sometimes a user has to use `EXPECT_TRUE()` to check a |
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complex expression, for lack of a better macro. This has the problem of not |
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showing you the values of the parts of the expression, making it hard to |
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understand what went wrong. As a workaround, some users choose to construct the |
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failure message by themselves, streaming it into `EXPECT_TRUE()`. However, this |
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is awkward especially when the expression has side-effects or is expensive to |
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evaluate. |
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GoogleTest gives you three different options to solve this problem: |
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#### Using an Existing Boolean Function |
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If you already have a function or functor that returns `bool` (or a type that |
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can be implicitly converted to `bool`), you can use it in a *predicate |
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assertion* to get the function arguments printed for free. See |
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[`EXPECT_PRED*`](reference/assertions.md#EXPECT_PRED) in the Assertions |
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Reference for details. |
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#### Using a Function That Returns an AssertionResult |
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While `EXPECT_PRED*()` and friends are handy for a quick job, the syntax is not |
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satisfactory: you have to use different macros for different arities, and it |
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feels more like Lisp than C++. The `::testing::AssertionResult` class solves |
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this problem. |
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An `AssertionResult` object represents the result of an assertion (whether it's |
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a success or a failure, and an associated message). You can create an |
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`AssertionResult` using one of these factory functions: |
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```c++ |
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namespace testing { |
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// Returns an AssertionResult object to indicate that an assertion has |
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// succeeded. |
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AssertionResult AssertionSuccess(); |
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// Returns an AssertionResult object to indicate that an assertion has |
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// failed. |
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AssertionResult AssertionFailure(); |
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} |
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``` |
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You can then use the `<<` operator to stream messages to the `AssertionResult` |
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object. |
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To provide more readable messages in Boolean assertions (e.g. `EXPECT_TRUE()`), |
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write a predicate function that returns `AssertionResult` instead of `bool`. For |
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example, if you define `IsEven()` as: |
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```c++ |
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testing::AssertionResult IsEven(int n) { |
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if ((n % 2) == 0) |
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return testing::AssertionSuccess(); |
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else |
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return testing::AssertionFailure() << n << " is odd"; |
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} |
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``` |
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instead of: |
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```c++ |
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bool IsEven(int n) { |
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return (n % 2) == 0; |
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} |
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``` |
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the failed assertion `EXPECT_TRUE(IsEven(Fib(4)))` will print: |
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```none |
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Value of: IsEven(Fib(4)) |
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Actual: false (3 is odd) |
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Expected: true |
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``` |
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instead of a more opaque |
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```none |
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Value of: IsEven(Fib(4)) |
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Actual: false |
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Expected: true |
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``` |
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If you want informative messages in `EXPECT_FALSE` and `ASSERT_FALSE` as well |
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(one third of Boolean assertions in the Google code base are negative ones), and |
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are fine with making the predicate slower in the success case, you can supply a |
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success message: |
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```c++ |
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testing::AssertionResult IsEven(int n) { |
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if ((n % 2) == 0) |
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return testing::AssertionSuccess() << n << " is even"; |
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else |
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return testing::AssertionFailure() << n << " is odd"; |
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} |
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``` |
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Then the statement `EXPECT_FALSE(IsEven(Fib(6)))` will print |
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```none |
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Value of: IsEven(Fib(6)) |
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Actual: true (8 is even) |
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Expected: false |
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``` |
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#### Using a Predicate-Formatter |
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If you find the default message generated by |
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[`EXPECT_PRED*`](reference/assertions.md#EXPECT_PRED) and |
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[`EXPECT_TRUE`](reference/assertions.md#EXPECT_TRUE) unsatisfactory, or some |
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arguments to your predicate do not support streaming to `ostream`, you can |
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instead use *predicate-formatter assertions* to *fully* customize how the |
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message is formatted. See |
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[`EXPECT_PRED_FORMAT*`](reference/assertions.md#EXPECT_PRED_FORMAT) in the |
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Assertions Reference for details. |
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### Floating-Point Comparison |
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See [Floating-Point Comparison](reference/assertions.md#floating-point) in the |
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Assertions Reference. |
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#### Floating-Point Predicate-Format Functions |
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Some floating-point operations are useful, but not that often used. In order to |
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avoid an explosion of new macros, we provide them as predicate-format functions |
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that can be used in the predicate assertion macro |
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[`EXPECT_PRED_FORMAT2`](reference/assertions.md#EXPECT_PRED_FORMAT), for |
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example: |
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```c++ |
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using ::testing::FloatLE; |
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using ::testing::DoubleLE; |
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... |
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EXPECT_PRED_FORMAT2(FloatLE, val1, val2); |
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EXPECT_PRED_FORMAT2(DoubleLE, val1, val2); |
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``` |
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The above code verifies that `val1` is less than, or approximately equal to, |
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`val2`. |
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### Asserting Using gMock Matchers |
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See [`EXPECT_THAT`](reference/assertions.md#EXPECT_THAT) in the Assertions |
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Reference. |
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### More String Assertions |
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(Please read the [previous](#asserting-using-gmock-matchers) section first if |
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you haven't.) |
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You can use the gMock [string matchers](reference/matchers.md#string-matchers) |
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with [`EXPECT_THAT`](reference/assertions.md#EXPECT_THAT) to do more string |
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comparison tricks (sub-string, prefix, suffix, regular expression, and etc). For |
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example, |
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```c++ |
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using ::testing::HasSubstr; |
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using ::testing::MatchesRegex; |
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... |
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ASSERT_THAT(foo_string, HasSubstr("needle")); |
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EXPECT_THAT(bar_string, MatchesRegex("\\w*\\d+")); |
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``` |
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### Windows HRESULT assertions |
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See [Windows HRESULT Assertions](reference/assertions.md#HRESULT) in the |
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Assertions Reference. |
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### Type Assertions |
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You can call the function |
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```c++ |
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::testing::StaticAssertTypeEq<T1, T2>(); |
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``` |
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to assert that types `T1` and `T2` are the same. The function does nothing if |
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the assertion is satisfied. If the types are different, the function call will |
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fail to compile, the compiler error message will say that `T1 and T2 are not the |
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same type` and most likely (depending on the compiler) show you the actual |
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values of `T1` and `T2`. This is mainly useful inside template code. |
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**Caveat**: When used inside a member function of a class template or a function |
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template, `StaticAssertTypeEq<T1, T2>()` is effective only if the function is |
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instantiated. For example, given: |
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```c++ |
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template <typename T> class Foo { |
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public: |
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void Bar() { testing::StaticAssertTypeEq<int, T>(); } |
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}; |
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``` |
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the code: |
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```c++ |
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void Test1() { Foo<bool> foo; } |
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``` |
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will not generate a compiler error, as `Foo<bool>::Bar()` is never actually |
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instantiated. Instead, you need: |
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```c++ |
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void Test2() { Foo<bool> foo; foo.Bar(); } |
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``` |
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to cause a compiler error. |
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### Assertion Placement |
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You can use assertions in any C++ function. In particular, it doesn't have to be |
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a method of the test fixture class. The one constraint is that assertions that |
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generate a fatal failure (`FAIL*` and `ASSERT_*`) can only be used in |
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void-returning functions. This is a consequence of Google's not using |
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exceptions. By placing it in a non-void function you'll get a confusing compile |
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error like `"error: void value not ignored as it ought to be"` or `"cannot |
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initialize return object of type 'bool' with an rvalue of type 'void'"` or |
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`"error: no viable conversion from 'void' to 'string'"`. |
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If you need to use fatal assertions in a function that returns non-void, one |
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option is to make the function return the value in an out parameter instead. For |
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example, you can rewrite `T2 Foo(T1 x)` to `void Foo(T1 x, T2* result)`. You |
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need to make sure that `*result` contains some sensible value even when the |
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function returns prematurely. As the function now returns `void`, you can use |
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any assertion inside of it. |
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If changing the function's type is not an option, you should just use assertions |
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that generate non-fatal failures, such as `ADD_FAILURE*` and `EXPECT_*`. |
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{: .callout .note} |
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NOTE: Constructors and destructors are not considered void-returning functions, |
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according to the C++ language specification, and so you may not use fatal |
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assertions in them; you'll get a compilation error if you try. Instead, either |
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call `abort` and crash the entire test executable, or put the fatal assertion in |
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a `SetUp`/`TearDown` function; see |
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[constructor/destructor vs. `SetUp`/`TearDown`](faq.md#CtorVsSetUp) |
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{: .callout .warning} |
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WARNING: A fatal assertion in a helper function (private void-returning method) |
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called from a constructor or destructor does not terminate the current test, as |
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your intuition might suggest: it merely returns from the constructor or |
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destructor early, possibly leaving your object in a partially-constructed or |
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partially-destructed state! You almost certainly want to `abort` or use |
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`SetUp`/`TearDown` instead. |
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## Skipping test execution |
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Related to the assertions `SUCCEED()` and `FAIL()`, you can prevent further test |
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execution at runtime with the `GTEST_SKIP()` macro. This is useful when you need |
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to check for preconditions of the system under test during runtime and skip |
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tests in a meaningful way. |
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`GTEST_SKIP()` can be used in individual test cases or in the `SetUp()` methods |
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of classes derived from either `::testing::Environment` or `::testing::Test`. |
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For example: |
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```c++ |
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TEST(SkipTest, DoesSkip) { |
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GTEST_SKIP() << "Skipping single test"; |
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FAIL(); // Won't fail; it won't be executed |
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} |
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class SkipFixture : public ::testing::Test { |
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protected: |
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void SetUp() override { |
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GTEST_SKIP() << "Skipping all tests for this fixture"; |
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} |
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}; |
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// Tests for SkipFixture won't be executed. |
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TEST_F(SkipFixture, SkipsOneTest) { |
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FAIL(); // Won't fail; it won't be executed |
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} |
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``` |
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As with assertion macros, you can stream a custom message into `GTEST_SKIP()`. |
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## Teaching GoogleTest How to Print Your Values |
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When a test assertion such as `EXPECT_EQ` fails, GoogleTest prints the argument |
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values to help you debug. It does this using a user-extensible value printer. |
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This printer knows how to print built-in C++ types, native arrays, STL |
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containers, and any type that supports the `<<` operator. For other types, it |
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prints the raw bytes in the value and hopes that you the user can figure it out. |
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As mentioned earlier, the printer is *extensible*. That means you can teach it |
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to do a better job at printing your particular type than to dump the bytes. To |
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do that, define an `AbslStringify()` overload as a `friend` function template |
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for your type: |
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```cpp |
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namespace foo { |
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class Point { // We want GoogleTest to be able to print instances of this. |
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... |
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// Provide a friend overload. |
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template <typename Sink> |
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friend void AbslStringify(Sink& sink, const Point& point) { |
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absl::Format(&sink, "(%d, %d)", point.x, point.y); |
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} |
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int x; |
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int y; |
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}; |
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// If you can't declare the function in the class it's important that the |
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// AbslStringify overload is defined in the SAME namespace that defines Point. |
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// C++'s look-up rules rely on that. |
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enum class EnumWithStringify { kMany = 0, kChoices = 1 }; |
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template <typename Sink> |
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void AbslStringify(Sink& sink, EnumWithStringify e) { |
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absl::Format(&sink, "%s", e == EnumWithStringify::kMany ? "Many" : "Choices"); |
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} |
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} // namespace foo |
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``` |
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{: .callout .note} |
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Note: `AbslStringify()` utilizes a generic "sink" buffer to construct its |
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string. For more information about supported operations on `AbslStringify()`'s |
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sink, see go/abslstringify. |
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`AbslStringify()` can also use `absl::StrFormat`'s catch-all `%v` type specifier |
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within its own format strings to perform type deduction. `Point` above could be |
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formatted as `"(%v, %v)"` for example, and deduce the `int` values as `%d`. |
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Sometimes, `AbslStringify()` might not be an option: your team may wish to print |
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types with extra debugging information for testing purposes only. If so, you can |
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instead define a `PrintTo()` function like this: |
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```c++ |
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#include <ostream> |
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namespace foo { |
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class Point { |
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... |
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friend void PrintTo(const Point& point, std::ostream* os) { |
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*os << "(" << point.x << "," << point.y << ")"; |
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} |
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int x; |
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int y; |
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}; |
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// If you can't declare the function in the class it's important that PrintTo() |
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// is defined in the SAME namespace that defines Point. C++'s look-up rules |
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// rely on that. |
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void PrintTo(const Point& point, std::ostream* os) { |
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*os << "(" << point.x << "," << point.y << ")"; |
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} |
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} // namespace foo |
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``` |
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If you have defined both `AbslStringify()` and `PrintTo()`, the latter will be |
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used by GoogleTest. This allows you to customize how the value appears in |
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GoogleTest's output without affecting code that relies on the behavior of |
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`AbslStringify()`. |
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If you have an existing `<<` operator and would like to define an |
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`AbslStringify()`, the latter will be used for GoogleTest printing. |
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If you want to print a value `x` using GoogleTest's value printer yourself, just |
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call `::testing::PrintToString(x)`, which returns an `std::string`: |
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```c++ |
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vector<pair<Point, int> > point_ints = GetPointIntVector(); |
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EXPECT_TRUE(IsCorrectPointIntVector(point_ints)) |
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<< "point_ints = " << testing::PrintToString(point_ints); |
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``` |
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For more details regarding `AbslStringify()` and its integration with other |
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libraries, see go/abslstringify. |
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## Death Tests |
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In many applications, there are assertions that can cause application failure if |
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a condition is not met. These consistency checks, which ensure that the program |
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is in a known good state, are there to fail at the earliest possible time after |
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some program state is corrupted. If the assertion checks the wrong condition, |
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then the program may proceed in an erroneous state, which could lead to memory |
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corruption, security holes, or worse. Hence it is vitally important to test that |
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such assertion statements work as expected. |
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Since these precondition checks cause the processes to die, we call such tests |
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_death tests_. More generally, any test that checks that a program terminates |
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(except by throwing an exception) in an expected fashion is also a death test. |
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Note that if a piece of code throws an exception, we don't consider it "death" |
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for the purpose of death tests, as the caller of the code could catch the |
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exception and avoid the crash. If you want to verify exceptions thrown by your |
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code, see [Exception Assertions](#ExceptionAssertions). |
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If you want to test `EXPECT_*()/ASSERT_*()` failures in your test code, see |
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["Catching" Failures](#catching-failures). |
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### How to Write a Death Test |
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GoogleTest provides assertion macros to support death tests. See |
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[Death Assertions](reference/assertions.md#death) in the Assertions Reference |
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for details. |
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To write a death test, simply use one of the macros inside your test function. |
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For example, |
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```c++ |
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TEST(MyDeathTest, Foo) { |
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// This death test uses a compound statement. |
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ASSERT_DEATH({ |
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int n = 5; |
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Foo(&n); |
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}, "Error on line .* of Foo()"); |
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} |
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TEST(MyDeathTest, NormalExit) { |
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EXPECT_EXIT(NormalExit(), testing::ExitedWithCode(0), "Success"); |
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} |
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TEST(MyDeathTest, KillProcess) { |
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EXPECT_EXIT(KillProcess(), testing::KilledBySignal(SIGKILL), |
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"Sending myself unblockable signal"); |
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} |
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``` |
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verifies that: |
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* calling `Foo(5)` causes the process to die with the given error message, |
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* calling `NormalExit()` causes the process to print `"Success"` to stderr and |
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exit with exit code 0, and |
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* calling `KillProcess()` kills the process with signal `SIGKILL`. |
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The test function body may contain other assertions and statements as well, if |
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necessary. |
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Note that a death test only cares about three things: |
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1. does `statement` abort or exit the process? |
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2. (in the case of `ASSERT_EXIT` and `EXPECT_EXIT`) does the exit status |
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satisfy `predicate`? Or (in the case of `ASSERT_DEATH` and `EXPECT_DEATH`) |
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is the exit status non-zero? And |
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3. does the stderr output match `matcher`? |
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In particular, if `statement` generates an `ASSERT_*` or `EXPECT_*` failure, it |
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will **not** cause the death test to fail, as GoogleTest assertions don't abort |
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the process. |
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### Death Test Naming |
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{: .callout .important} |
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IMPORTANT: We strongly recommend you to follow the convention of naming your |
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**test suite** (not test) `*DeathTest` when it contains a death test, as |
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demonstrated in the above example. The |
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[Death Tests And Threads](#death-tests-and-threads) section below explains why. |
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If a test fixture class is shared by normal tests and death tests, you can use |
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`using` or `typedef` to introduce an alias for the fixture class and avoid |
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duplicating its code: |
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```c++ |
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class FooTest : public testing::Test { ... }; |
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using FooDeathTest = FooTest; |
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TEST_F(FooTest, DoesThis) { |
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// normal test |
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} |
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TEST_F(FooDeathTest, DoesThat) { |
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// death test |
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} |
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``` |
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### Regular Expression Syntax |
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When built with Bazel and using Abseil, GoogleTest uses the |
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[RE2](https://github.com/google/re2/wiki/Syntax) syntax. Otherwise, for POSIX |
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systems (Linux, Cygwin, Mac), GoogleTest uses the |
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[POSIX extended regular expression](https://www.opengroup.org/onlinepubs/009695399/basedefs/xbd_chap09.html#tag_09_04) |
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syntax. To learn about POSIX syntax, you may want to read this |
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[Wikipedia entry](https://en.wikipedia.org/wiki/Regular_expression#POSIX_extended). |
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On Windows, GoogleTest uses its own simple regular expression implementation. It |
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lacks many features. For example, we don't support union (`"x|y"`), grouping |
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(`"(xy)"`), brackets (`"[xy]"`), and repetition count (`"x{5,7}"`), among |
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others. Below is what we do support (`A` denotes a literal character, period |
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(`.`), or a single `\\ ` escape sequence; `x` and `y` denote regular |
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expressions.): |
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Expression | Meaning |
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---------- | -------------------------------------------------------------- |
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`c` | matches any literal character `c` |
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`\\d` | matches any decimal digit |
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`\\D` | matches any character that's not a decimal digit |
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`\\f` | matches `\f` |
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`\\n` | matches `\n` |
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`\\r` | matches `\r` |
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`\\s` | matches any ASCII whitespace, including `\n` |
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`\\S` | matches any character that's not a whitespace |
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`\\t` | matches `\t` |
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`\\v` | matches `\v` |
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`\\w` | matches any letter, `_`, or decimal digit |
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`\\W` | matches any character that `\\w` doesn't match |
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`\\c` | matches any literal character `c`, which must be a punctuation |
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`.` | matches any single character except `\n` |
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`A?` | matches 0 or 1 occurrences of `A` |
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`A*` | matches 0 or many occurrences of `A` |
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`A+` | matches 1 or many occurrences of `A` |
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`^` | matches the beginning of a string (not that of each line) |
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`$` | matches the end of a string (not that of each line) |
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`xy` | matches `x` followed by `y` |
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To help you determine which capability is available on your system, GoogleTest |
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defines macros to govern which regular expression it is using. The macros are: |
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`GTEST_USES_SIMPLE_RE=1` or `GTEST_USES_POSIX_RE=1`. If you want your death |
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tests to work in all cases, you can either `#if` on these macros or use the more |
|
limited syntax only. |
|
|
|
### How It Works |
|
|
|
See [Death Assertions](reference/assertions.md#death) in the Assertions |
|
Reference. |
|
|
|
### Death Tests And Threads |
|
|
|
The reason for the two death test styles has to do with thread safety. Due to |
|
well-known problems with forking in the presence of threads, death tests should |
|
be run in a single-threaded context. Sometimes, however, it isn't feasible to |
|
arrange that kind of environment. For example, statically-initialized modules |
|
may start threads before main is ever reached. Once threads have been created, |
|
it may be difficult or impossible to clean them up. |
|
|
|
GoogleTest has three features intended to raise awareness of threading issues. |
|
|
|
1. A warning is emitted if multiple threads are running when a death test is |
|
encountered. |
|
2. Test suites with a name ending in "DeathTest" are run before all other |
|
tests. |
|
3. It uses `clone()` instead of `fork()` to spawn the child process on Linux |
|
(`clone()` is not available on Cygwin and Mac), as `fork()` is more likely |
|
to cause the child to hang when the parent process has multiple threads. |
|
|
|
It's perfectly fine to create threads inside a death test statement; they are |
|
executed in a separate process and cannot affect the parent. |
|
|
|
### Death Test Styles |
|
|
|
The "threadsafe" death test style was introduced in order to help mitigate the |
|
risks of testing in a possibly multithreaded environment. It trades increased |
|
test execution time (potentially dramatically so) for improved thread safety. |
|
|
|
The automated testing framework does not set the style flag. You can choose a |
|
particular style of death tests by setting the flag programmatically: |
|
|
|
```c++ |
|
GTEST_FLAG_SET(death_test_style, "threadsafe"); |
|
``` |
|
|
|
You can do this in `main()` to set the style for all death tests in the binary, |
|
or in individual tests. Recall that flags are saved before running each test and |
|
restored afterwards, so you need not do that yourself. For example: |
|
|
|
```c++ |
|
int main(int argc, char** argv) { |
|
testing::InitGoogleTest(&argc, argv); |
|
GTEST_FLAG_SET(death_test_style, "fast"); |
|
return RUN_ALL_TESTS(); |
|
} |
|
|
|
TEST(MyDeathTest, TestOne) { |
|
GTEST_FLAG_SET(death_test_style, "threadsafe"); |
|
// This test is run in the "threadsafe" style: |
|
ASSERT_DEATH(ThisShouldDie(), ""); |
|
} |
|
|
|
TEST(MyDeathTest, TestTwo) { |
|
// This test is run in the "fast" style: |
|
ASSERT_DEATH(ThisShouldDie(), ""); |
|
} |
|
``` |
|
|
|
### Caveats |
|
|
|
The `statement` argument of `ASSERT_EXIT()` can be any valid C++ statement. If |
|
it leaves the current function via a `return` statement or by throwing an |
|
exception, the death test is considered to have failed. Some GoogleTest macros |
|
may return from the current function (e.g. `ASSERT_TRUE()`), so be sure to avoid |
|
them in `statement`. |
|
|
|
Since `statement` runs in the child process, any in-memory side effect (e.g. |
|
modifying a variable, releasing memory, etc) it causes will *not* be observable |
|
in the parent process. In particular, if you release memory in a death test, |
|
your program will fail the heap check as the parent process will never see the |
|
memory reclaimed. To solve this problem, you can |
|
|
|
1. try not to free memory in a death test; |
|
2. free the memory again in the parent process; or |
|
3. do not use the heap checker in your program. |
|
|
|
Due to an implementation detail, you cannot place multiple death test assertions |
|
on the same line; otherwise, compilation will fail with an unobvious error |
|
message. |
|
|
|
Despite the improved thread safety afforded by the "threadsafe" style of death |
|
test, thread problems such as deadlock are still possible in the presence of |
|
handlers registered with `pthread_atfork(3)`. |
|
|
|
## Using Assertions in Sub-routines |
|
|
|
{: .callout .note} |
|
Note: If you want to put a series of test assertions in a subroutine to check |
|
for a complex condition, consider using |
|
[a custom GMock matcher](gmock_cook_book.md#NewMatchers) instead. This lets you |
|
provide a more readable error message in case of failure and avoid all of the |
|
issues described below. |
|
|
|
### Adding Traces to Assertions |
|
|
|
If a test sub-routine is called from several places, when an assertion inside it |
|
fails, it can be hard to tell which invocation of the sub-routine the failure is |
|
from. You can alleviate this problem using extra logging or custom failure |
|
messages, but that usually clutters up your tests. A better solution is to use |
|
the `SCOPED_TRACE` macro or the `ScopedTrace` utility: |
|
|
|
```c++ |
|
SCOPED_TRACE(message); |
|
``` |
|
|
|
```c++ |
|
ScopedTrace trace("file_path", line_number, message); |
|
``` |
|
|
|
where `message` can be anything streamable to `std::ostream`. `SCOPED_TRACE` |
|
macro will cause the current file name, line number, and the given message to be |
|
added in every failure message. `ScopedTrace` accepts explicit file name and |
|
line number in arguments, which is useful for writing test helpers. The effect |
|
will be undone when the control leaves the current lexical scope. |
|
|
|
For example, |
|
|
|
```c++ |
|
10: void Sub1(int n) { |
|
11: EXPECT_EQ(Bar(n), 1); |
|
12: EXPECT_EQ(Bar(n + 1), 2); |
|
13: } |
|
14: |
|
15: TEST(FooTest, Bar) { |
|
16: { |
|
17: SCOPED_TRACE("A"); // This trace point will be included in |
|
18: // every failure in this scope. |
|
19: Sub1(1); |
|
20: } |
|
21: // Now it won't. |
|
22: Sub1(9); |
|
23: } |
|
``` |
|
|
|
could result in messages like these: |
|
|
|
```none |
|
path/to/foo_test.cc:11: Failure |
|
Value of: Bar(n) |
|
Expected: 1 |
|
Actual: 2 |
|
Google Test trace: |
|
path/to/foo_test.cc:17: A |
|
|
|
path/to/foo_test.cc:12: Failure |
|
Value of: Bar(n + 1) |
|
Expected: 2 |
|
Actual: 3 |
|
``` |
|
|
|
Without the trace, it would've been difficult to know which invocation of |
|
`Sub1()` the two failures come from respectively. (You could add an extra |
|
message to each assertion in `Sub1()` to indicate the value of `n`, but that's |
|
tedious.) |
|
|
|
Some tips on using `SCOPED_TRACE`: |
|
|
|
1. With a suitable message, it's often enough to use `SCOPED_TRACE` at the |
|
beginning of a sub-routine, instead of at each call site. |
|
2. When calling sub-routines inside a loop, make the loop iterator part of the |
|
message in `SCOPED_TRACE` such that you can know which iteration the failure |
|
is from. |
|
3. Sometimes the line number of the trace point is enough for identifying the |
|
particular invocation of a sub-routine. In this case, you don't have to |
|
choose a unique message for `SCOPED_TRACE`. You can simply use `""`. |
|
4. You can use `SCOPED_TRACE` in an inner scope when there is one in the outer |
|
scope. In this case, all active trace points will be included in the failure |
|
messages, in reverse order they are encountered. |
|
5. The trace dump is clickable in Emacs - hit `return` on a line number and |
|
you'll be taken to that line in the source file! |
|
|
|
### Propagating Fatal Failures |
|
|
|
A common pitfall when using `ASSERT_*` and `FAIL*` is not understanding that |
|
when they fail they only abort the _current function_, not the entire test. For |
|
example, the following test will segfault: |
|
|
|
```c++ |
|
void Subroutine() { |
|
// Generates a fatal failure and aborts the current function. |
|
ASSERT_EQ(1, 2); |
|
|
|
// The following won't be executed. |
|
... |
|
} |
|
|
|
TEST(FooTest, Bar) { |
|
Subroutine(); // The intended behavior is for the fatal failure |
|
// in Subroutine() to abort the entire test. |
|
|
|
// The actual behavior: the function goes on after Subroutine() returns. |
|
int* p = nullptr; |
|
*p = 3; // Segfault! |
|
} |
|
``` |
|
|
|
To alleviate this, GoogleTest provides three different solutions. You could use |
|
either exceptions, the `(ASSERT|EXPECT)_NO_FATAL_FAILURE` assertions or the |
|
`HasFatalFailure()` function. They are described in the following two |
|
subsections. |
|
|
|
#### Asserting on Subroutines with an exception |
|
|
|
The following code can turn ASSERT-failure into an exception: |
|
|
|
```c++ |
|
class ThrowListener : public testing::EmptyTestEventListener { |
|
void OnTestPartResult(const testing::TestPartResult& result) override { |
|
if (result.type() == testing::TestPartResult::kFatalFailure) { |
|
throw testing::AssertionException(result); |
|
} |
|
} |
|
}; |
|
int main(int argc, char** argv) { |
|
... |
|
testing::UnitTest::GetInstance()->listeners().Append(new ThrowListener); |
|
return RUN_ALL_TESTS(); |
|
} |
|
``` |
|
|
|
This listener should be added after other listeners if you have any, otherwise |
|
they won't see failed `OnTestPartResult`. |
|
|
|
#### Asserting on Subroutines |
|
|
|
As shown above, if your test calls a subroutine that has an `ASSERT_*` failure |
|
in it, the test will continue after the subroutine returns. This may not be what |
|
you want. |
|
|
|
Often people want fatal failures to propagate like exceptions. For that |
|
GoogleTest offers the following macros: |
|
|
|
Fatal assertion | Nonfatal assertion | Verifies |
|
------------------------------------- | ------------------------------------- | -------- |
|
`ASSERT_NO_FATAL_FAILURE(statement);` | `EXPECT_NO_FATAL_FAILURE(statement);` | `statement` doesn't generate any new fatal failures in the current thread. |
|
|
|
Only failures in the thread that executes the assertion are checked to determine |
|
the result of this type of assertions. If `statement` creates new threads, |
|
failures in these threads are ignored. |
|
|
|
Examples: |
|
|
|
```c++ |
|
ASSERT_NO_FATAL_FAILURE(Foo()); |
|
|
|
int i; |
|
EXPECT_NO_FATAL_FAILURE({ |
|
i = Bar(); |
|
}); |
|
``` |
|
|
|
Assertions from multiple threads are currently not supported on Windows. |
|
|
|
#### Checking for Failures in the Current Test |
|
|
|
`HasFatalFailure()` in the `::testing::Test` class returns `true` if an |
|
assertion in the current test has suffered a fatal failure. This allows |
|
functions to catch fatal failures in a sub-routine and return early. |
|
|
|
```c++ |
|
class Test { |
|
public: |
|
... |
|
static bool HasFatalFailure(); |
|
}; |
|
``` |
|
|
|
The typical usage, which basically simulates the behavior of a thrown exception, |
|
is: |
|
|
|
```c++ |
|
TEST(FooTest, Bar) { |
|
Subroutine(); |
|
// Aborts if Subroutine() had a fatal failure. |
|
if (HasFatalFailure()) return; |
|
|
|
// The following won't be executed. |
|
... |
|
} |
|
``` |
|
|
|
If `HasFatalFailure()` is used outside of `TEST()` , `TEST_F()` , or a test |
|
fixture, you must add the `::testing::Test::` prefix, as in: |
|
|
|
```c++ |
|
if (testing::Test::HasFatalFailure()) return; |
|
``` |
|
|
|
Similarly, `HasNonfatalFailure()` returns `true` if the current test has at |
|
least one non-fatal failure, and `HasFailure()` returns `true` if the current |
|
test has at least one failure of either kind. |
|
|
|
## Logging Additional Information |
|
|
|
In your test code, you can call `RecordProperty("key", value)` to log additional |
|
information, where `value` can be either a string or an `int`. The *last* value |
|
recorded for a key will be emitted to the |
|
[XML output](#generating-an-xml-report) if you specify one. For example, the |
|
test |
|
|
|
```c++ |
|
TEST_F(WidgetUsageTest, MinAndMaxWidgets) { |
|
RecordProperty("MaximumWidgets", ComputeMaxUsage()); |
|
RecordProperty("MinimumWidgets", ComputeMinUsage()); |
|
} |
|
``` |
|
|
|
will output XML like this: |
|
|
|
```xml |
|
... |
|
<testcase name="MinAndMaxWidgets" file="test.cpp" line="1" status="run" time="0.006" classname="WidgetUsageTest" MaximumWidgets="12" MinimumWidgets="9" /> |
|
... |
|
``` |
|
|
|
{: .callout .note} |
|
> NOTE: |
|
> |
|
> * `RecordProperty()` is a static member of the `Test` class. Therefore it |
|
> needs to be prefixed with `::testing::Test::` if used outside of the |
|
> `TEST` body and the test fixture class. |
|
> * *`key`* must be a valid XML attribute name, and cannot conflict with the |
|
> ones already used by GoogleTest (`name`, `status`, `time`, `classname`, |
|
> `type_param`, and `value_param`). |
|
> * Calling `RecordProperty()` outside of the lifespan of a test is allowed. |
|
> If it's called outside of a test but between a test suite's |
|
> `SetUpTestSuite()` and `TearDownTestSuite()` methods, it will be |
|
> attributed to the XML element for the test suite. If it's called outside |
|
> of all test suites (e.g. in a test environment), it will be attributed to |
|
> the top-level XML element. |
|
|
|
## Sharing Resources Between Tests in the Same Test Suite |
|
|
|
GoogleTest creates a new test fixture object for each test in order to make |
|
tests independent and easier to debug. However, sometimes tests use resources |
|
that are expensive to set up, making the one-copy-per-test model prohibitively |
|
expensive. |
|
|
|
If the tests don't change the resource, there's no harm in their sharing a |
|
single resource copy. So, in addition to per-test set-up/tear-down, GoogleTest |
|
also supports per-test-suite set-up/tear-down. To use it: |
|
|
|
1. In your test fixture class (say `FooTest` ), declare as `static` some member |
|
variables to hold the shared resources. |
|
2. Outside your test fixture class (typically just below it), define those |
|
member variables, optionally giving them initial values. |
|
3. In the same test fixture class, define a public member function `static void |
|
SetUpTestSuite()` (remember not to spell it as **`SetupTestSuite`** with a |
|
small `u`!) to set up the shared resources and a `static void |
|
TearDownTestSuite()` function to tear them down. |
|
|
|
That's it! GoogleTest automatically calls `SetUpTestSuite()` before running the |
|
*first test* in the `FooTest` test suite (i.e. before creating the first |
|
`FooTest` object), and calls `TearDownTestSuite()` after running the *last test* |
|
in it (i.e. after deleting the last `FooTest` object). In between, the tests can |
|
use the shared resources. |
|
|
|
Remember that the test order is undefined, so your code can't depend on a test |
|
preceding or following another. Also, the tests must either not modify the state |
|
of any shared resource, or, if they do modify the state, they must restore the |
|
state to its original value before passing control to the next test. |
|
|
|
Note that `SetUpTestSuite()` may be called multiple times for a test fixture |
|
class that has derived classes, so you should not expect code in the function |
|
body to be run only once. Also, derived classes still have access to shared |
|
resources defined as static members, so careful consideration is needed when |
|
managing shared resources to avoid memory leaks if shared resources are not |
|
properly cleaned up in `TearDownTestSuite()`. |
|
|
|
Here's an example of per-test-suite set-up and tear-down: |
|
|
|
```c++ |
|
class FooTest : public testing::Test { |
|
protected: |
|
// Per-test-suite set-up. |
|
// Called before the first test in this test suite. |
|
// Can be omitted if not needed. |
|
static void SetUpTestSuite() { |
|
shared_resource_ = new ...; |
|
|
|
// If `shared_resource_` is **not deleted** in `TearDownTestSuite()`, |
|
// reallocation should be prevented because `SetUpTestSuite()` may be called |
|
// in subclasses of FooTest and lead to memory leak. |
|
// |
|
// if (shared_resource_ == nullptr) { |
|
// shared_resource_ = new ...; |
|
// } |
|
} |
|
|
|
// Per-test-suite tear-down. |
|
// Called after the last test in this test suite. |
|
// Can be omitted if not needed. |
|
static void TearDownTestSuite() { |
|
delete shared_resource_; |
|
shared_resource_ = nullptr; |
|
} |
|
|
|
// You can define per-test set-up logic as usual. |
|
void SetUp() override { ... } |
|
|
|
// You can define per-test tear-down logic as usual. |
|
void TearDown() override { ... } |
|
|
|
// Some expensive resource shared by all tests. |
|
static T* shared_resource_; |
|
}; |
|
|
|
T* FooTest::shared_resource_ = nullptr; |
|
|
|
TEST_F(FooTest, Test1) { |
|
... you can refer to shared_resource_ here ... |
|
} |
|
|
|
TEST_F(FooTest, Test2) { |
|
... you can refer to shared_resource_ here ... |
|
} |
|
``` |
|
|
|
{: .callout .note} |
|
NOTE: Though the above code declares `SetUpTestSuite()` protected, it may |
|
sometimes be necessary to declare it public, such as when using it with |
|
`TEST_P`. |
|
|
|
## Global Set-Up and Tear-Down |
|
|
|
Just as you can do set-up and tear-down at the test level and the test suite |
|
level, you can also do it at the test program level. Here's how. |
|
|
|
First, you subclass the `::testing::Environment` class to define a test |
|
environment, which knows how to set-up and tear-down: |
|
|
|
```c++ |
|
class Environment : public ::testing::Environment { |
|
public: |
|
~Environment() override {} |
|
|
|
// Override this to define how to set up the environment. |
|
void SetUp() override {} |
|
|
|
// Override this to define how to tear down the environment. |
|
void TearDown() override {} |
|
}; |
|
``` |
|
|
|
Then, you register an instance of your environment class with GoogleTest by |
|
calling the `::testing::AddGlobalTestEnvironment()` function: |
|
|
|
```c++ |
|
Environment* AddGlobalTestEnvironment(Environment* env); |
|
``` |
|
|
|
Now, when `RUN_ALL_TESTS()` is invoked, it first calls the `SetUp()` method. The |
|
tests are then executed, provided that none of the environments have reported |
|
fatal failures and `GTEST_SKIP()` has not been invoked. Finally, `TearDown()` is |
|
called. |
|
|
|
Note that `SetUp()` and `TearDown()` are only invoked if there is at least one |
|
test to be performed. Importantly, `TearDown()` is executed even if the test is |
|
not run due to a fatal failure or `GTEST_SKIP()`. |
|
|
|
Calling `SetUp()` and `TearDown()` for each iteration depends on the flag |
|
`gtest_recreate_environments_when_repeating`. `SetUp()` and `TearDown()` are |
|
called for each environment object when the object is recreated for each |
|
iteration. However, if test environments are not recreated for each iteration, |
|
`SetUp()` is called only on the first iteration, and `TearDown()` is called only |
|
on the last iteration. |
|
|
|
It's OK to register multiple environment objects. In this suite, their `SetUp()` |
|
will be called in the order they are registered, and their `TearDown()` will be |
|
called in the reverse order. |
|
|
|
Note that GoogleTest takes ownership of the registered environment objects. |
|
Therefore **do not delete them** by yourself. |
|
|
|
You should call `AddGlobalTestEnvironment()` before `RUN_ALL_TESTS()` is called, |
|
probably in `main()`. If you use `gtest_main`, you need to call this before |
|
`main()` starts for it to take effect. One way to do this is to define a global |
|
variable like this: |
|
|
|
```c++ |
|
testing::Environment* const foo_env = |
|
testing::AddGlobalTestEnvironment(new FooEnvironment); |
|
``` |
|
|
|
However, we strongly recommend you to write your own `main()` and call |
|
`AddGlobalTestEnvironment()` there, as relying on initialization of global |
|
variables makes the code harder to read and may cause problems when you register |
|
multiple environments from different translation units and the environments have |
|
dependencies among them (remember that the compiler doesn't guarantee the order |
|
in which global variables from different translation units are initialized). |
|
|
|
## Value-Parameterized Tests |
|
|
|
*Value-parameterized tests* allow you to test your code with different |
|
parameters without writing multiple copies of the same test. This is useful in a |
|
number of situations, for example: |
|
|
|
* You have a piece of code whose behavior is affected by one or more |
|
command-line flags. You want to make sure your code performs correctly for |
|
various values of those flags. |
|
* You want to test different implementations of an OO interface. |
|
* You want to test your code over various inputs (a.k.a. data-driven testing). |
|
This feature is easy to abuse, so please exercise your good sense when doing |
|
it! |
|
|
|
### How to Write Value-Parameterized Tests |
|
|
|
To write value-parameterized tests, first you should define a fixture class. It |
|
must be derived from both `testing::Test` and `testing::WithParamInterface<T>` |
|
(the latter is a pure interface), where `T` is the type of your parameter |
|
values. For convenience, you can just derive the fixture class from |
|
`testing::TestWithParam<T>`, which itself is derived from both `testing::Test` |
|
and `testing::WithParamInterface<T>`. `T` can be any copyable type. If it's a |
|
raw pointer, you are responsible for managing the lifespan of the pointed |
|
values. |
|
|
|
{: .callout .note} |
|
NOTE: If your test fixture defines `SetUpTestSuite()` or `TearDownTestSuite()` |
|
they must be declared **public** rather than **protected** in order to use |
|
`TEST_P`. |
|
|
|
```c++ |
|
class FooTest : |
|
public testing::TestWithParam<absl::string_view> { |
|
// You can implement all the usual fixture class members here. |
|
// To access the test parameter, call GetParam() from class |
|
// TestWithParam<T>. |
|
}; |
|
|
|
// Or, when you want to add parameters to a pre-existing fixture class: |
|
class BaseTest : public testing::Test { |
|
... |
|
}; |
|
class BarTest : public BaseTest, |
|
public testing::WithParamInterface<absl::string_view> { |
|
... |
|
}; |
|
``` |
|
|
|
Then, use the `TEST_P` macro to define as many test patterns using this fixture |
|
as you want. The `_P` suffix is for "parameterized" or "pattern", whichever you |
|
prefer to think. |
|
|
|
```c++ |
|
TEST_P(FooTest, DoesBlah) { |
|
// Inside a test, access the test parameter with the GetParam() method |
|
// of the TestWithParam<T> class: |
|
EXPECT_TRUE(foo.Blah(GetParam())); |
|
... |
|
} |
|
|
|
TEST_P(FooTest, HasBlahBlah) { |
|
... |
|
} |
|
``` |
|
|
|
Finally, you can use the `INSTANTIATE_TEST_SUITE_P` macro to instantiate the |
|
test suite with any set of parameters you want. GoogleTest defines a number of |
|
functions for generating test parameters—see details at |
|
[`INSTANTIATE_TEST_SUITE_P`](reference/testing.md#INSTANTIATE_TEST_SUITE_P) in |
|
the Testing Reference. |
|
|
|
For example, the following statement will instantiate tests from the `FooTest` |
|
test suite each with parameter values `"meeny"`, `"miny"`, and `"moe"` using the |
|
[`Values`](reference/testing.md#param-generators) parameter generator: |
|
|
|
```c++ |
|
INSTANTIATE_TEST_SUITE_P(MeenyMinyMoe, |
|
FooTest, |
|
testing::Values("meeny", "miny", "moe")); |
|
``` |
|
|
|
{: .callout .note} |
|
NOTE: The code above must be placed at global or namespace scope, not at |
|
function scope. |
|
|
|
The first argument to `INSTANTIATE_TEST_SUITE_P` is a unique name for the |
|
instantiation of the test suite. The next argument is the name of the test |
|
pattern, and the last is the |
|
[parameter generator](reference/testing.md#param-generators). |
|
|
|
The parameter generator expression is not evaluated until GoogleTest is |
|
initialized (via `InitGoogleTest()`). Any prior initialization done in the |
|
`main` function will be accessible from the parameter generator, for example, |
|
the results of flag parsing. |
|
|
|
You can instantiate a test pattern more than once, so to distinguish different |
|
instances of the pattern, the instantiation name is added as a prefix to the |
|
actual test suite name. Remember to pick unique prefixes for different |
|
instantiations. The tests from the instantiation above will have these names: |
|
|
|
* `MeenyMinyMoe/FooTest.DoesBlah/0` for `"meeny"` |
|
* `MeenyMinyMoe/FooTest.DoesBlah/1` for `"miny"` |
|
* `MeenyMinyMoe/FooTest.DoesBlah/2` for `"moe"` |
|
* `MeenyMinyMoe/FooTest.HasBlahBlah/0` for `"meeny"` |
|
* `MeenyMinyMoe/FooTest.HasBlahBlah/1` for `"miny"` |
|
* `MeenyMinyMoe/FooTest.HasBlahBlah/2` for `"moe"` |
|
|
|
You can use these names in [`--gtest_filter`](#running-a-subset-of-the-tests). |
|
|
|
The following statement will instantiate all tests from `FooTest` again, each |
|
with parameter values `"cat"` and `"dog"` using the |
|
[`ValuesIn`](reference/testing.md#param-generators) parameter generator: |
|
|
|
```c++ |
|
constexpr absl::string_view kPets[] = {"cat", "dog"}; |
|
INSTANTIATE_TEST_SUITE_P(Pets, FooTest, testing::ValuesIn(kPets)); |
|
``` |
|
|
|
The tests from the instantiation above will have these names: |
|
|
|
* `Pets/FooTest.DoesBlah/0` for `"cat"` |
|
* `Pets/FooTest.DoesBlah/1` for `"dog"` |
|
* `Pets/FooTest.HasBlahBlah/0` for `"cat"` |
|
* `Pets/FooTest.HasBlahBlah/1` for `"dog"` |
|
|
|
Please note that `INSTANTIATE_TEST_SUITE_P` will instantiate *all* tests in the |
|
given test suite, whether their definitions come before or *after* the |
|
`INSTANTIATE_TEST_SUITE_P` statement. |
|
|
|
Additionally, by default, every `TEST_P` without a corresponding |
|
`INSTANTIATE_TEST_SUITE_P` causes a failing test in test suite |
|
`GoogleTestVerification`. If you have a test suite where that omission is not an |
|
error, for example it is in a library that may be linked in for other reasons or |
|
where the list of test cases is dynamic and may be empty, then this check can be |
|
suppressed by tagging the test suite: |
|
|
|
```c++ |
|
GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(FooTest); |
|
``` |
|
|
|
You can see [sample7_unittest.cc] and [sample8_unittest.cc] for more examples. |
|
|
|
[sample7_unittest.cc]: https://github.com/google/googletest/blob/main/googletest/samples/sample7_unittest.cc "Parameterized Test example" |
|
[sample8_unittest.cc]: https://github.com/google/googletest/blob/main/googletest/samples/sample8_unittest.cc "Parameterized Test example with multiple parameters" |
|
|
|
### Creating Value-Parameterized Abstract Tests |
|
|
|
In the above, we define and instantiate `FooTest` in the *same* source file. |
|
Sometimes you may want to define value-parameterized tests in a library and let |
|
other people instantiate them later. This pattern is known as *abstract tests*. |
|
As an example of its application, when you are designing an interface you can |
|
write a standard suite of abstract tests (perhaps using a factory function as |
|
the test parameter) that all implementations of the interface are expected to |
|
pass. When someone implements the interface, they can instantiate your suite to |
|
get all the interface-conformance tests for free. |
|
|
|
To define abstract tests, you should organize your code like this: |
|
|
|
1. Put the definition of the parameterized test fixture class (e.g. `FooTest`) |
|
in a header file, say `foo_param_test.h`. Think of this as *declaring* your |
|
abstract tests. |
|
2. Put the `TEST_P` definitions in `foo_param_test.cc`, which includes |
|
`foo_param_test.h`. Think of this as *implementing* your abstract tests. |
|
|
|
Once they are defined, you can instantiate them by including `foo_param_test.h`, |
|
invoking `INSTANTIATE_TEST_SUITE_P()`, and depending on the library target that |
|
contains `foo_param_test.cc`. You can instantiate the same abstract test suite |
|
multiple times, possibly in different source files. |
|
|
|
### Specifying Names for Value-Parameterized Test Parameters |
|
|
|
The optional last argument to `INSTANTIATE_TEST_SUITE_P()` allows the user to |
|
specify a function or functor that generates custom test name suffixes based on |
|
the test parameters. The function should accept one argument of type |
|
`testing::TestParamInfo<class ParamType>`, and return `std::string`. |
|
|
|
`testing::PrintToStringParamName` is a builtin test suffix generator that |
|
returns the value of `testing::PrintToString(GetParam())`. It does not work for |
|
`std::string` or C strings. |
|
|
|
{: .callout .note} |
|
NOTE: test names must be non-empty, unique, and may only contain ASCII |
|
alphanumeric characters. In particular, they |
|
[should not contain underscores](faq.md#why-should-test-suite-names-and-test-names-not-contain-underscore) |
|
|
|
```c++ |
|
class MyTestSuite : public testing::TestWithParam<int> {}; |
|
|
|
TEST_P(MyTestSuite, MyTest) |
|
{ |
|
std::cout << "Example Test Param: " << GetParam() << std::endl; |
|
} |
|
|
|
INSTANTIATE_TEST_SUITE_P(MyGroup, MyTestSuite, testing::Range(0, 10), |
|
testing::PrintToStringParamName()); |
|
``` |
|
|
|
Providing a custom functor allows for more control over test parameter name |
|
generation, especially for types where the automatic conversion does not |
|
generate helpful parameter names (e.g. strings as demonstrated above). The |
|
following example illustrates this for multiple parameters, an enumeration type |
|
and a string, and also demonstrates how to combine generators. It uses a lambda |
|
for conciseness: |
|
|
|
```c++ |
|
enum class MyType { MY_FOO = 0, MY_BAR = 1 }; |
|
|
|
class MyTestSuite : public testing::TestWithParam<std::tuple<MyType, std::string>> { |
|
}; |
|
|
|
INSTANTIATE_TEST_SUITE_P( |
|
MyGroup, MyTestSuite, |
|
testing::Combine( |
|
testing::Values(MyType::MY_FOO, MyType::MY_BAR), |
|
testing::Values("A", "B")), |
|
[](const testing::TestParamInfo<MyTestSuite::ParamType>& info) { |
|
std::string name = absl::StrCat( |
|
std::get<0>(info.param) == MyType::MY_FOO ? "Foo" : "Bar", |
|
std::get<1>(info.param)); |
|
absl::c_replace_if(name, [](char c) { return !std::isalnum(c); }, '_'); |
|
return name; |
|
}); |
|
``` |
|
|
|
## Typed Tests |
|
|
|
Suppose you have multiple implementations of the same interface and want to make |
|
sure that all of them satisfy some common requirements. Or, you may have defined |
|
several types that are supposed to conform to the same "concept" and you want to |
|
verify it. In both cases, you want the same test logic repeated for different |
|
types. |
|
|
|
While you can write one `TEST` or `TEST_F` for each type you want to test (and |
|
you may even factor the test logic into a function template that you invoke from |
|
the `TEST`), it's tedious and doesn't scale: if you want `m` tests over `n` |
|
types, you'll end up writing `m*n` `TEST`s. |
|
|
|
*Typed tests* allow you to repeat the same test logic over a list of types. You |
|
only need to write the test logic once, although you must know the type list |
|
when writing typed tests. Here's how you do it: |
|
|
|
First, define a fixture class template. It should be parameterized by a type. |
|
Remember to derive it from `::testing::Test`: |
|
|
|
```c++ |
|
template <typename T> |
|
class FooTest : public testing::Test { |
|
public: |
|
... |
|
using List = std::list<T>; |
|
static T shared_; |
|
T value_; |
|
}; |
|
``` |
|
|
|
Next, associate a list of types with the test suite, which will be repeated for |
|
each type in the list: |
|
|
|
```c++ |
|
using MyTypes = ::testing::Types<char, int, unsigned int>; |
|
TYPED_TEST_SUITE(FooTest, MyTypes); |
|
``` |
|
|
|
The type alias (`using` or `typedef`) is necessary for the `TYPED_TEST_SUITE` |
|
macro to parse correctly. Otherwise the compiler will think that each comma in |
|
the type list introduces a new macro argument. |
|
|
|
Then, use `TYPED_TEST()` instead of `TEST_F()` to define a typed test for this |
|
test suite. You can repeat this as many times as you want: |
|
|
|
```c++ |
|
TYPED_TEST(FooTest, DoesBlah) { |
|
// Inside a test, refer to the special name TypeParam to get the type |
|
// parameter. Since we are inside a derived class template, C++ requires |
|
// us to visit the members of FooTest via 'this'. |
|
TypeParam n = this->value_; |
|
|
|
// To visit static members of the fixture, add the 'TestFixture::' |
|
// prefix. |
|
n += TestFixture::shared_; |
|
|
|
// To refer to typedefs in the fixture, add the 'typename TestFixture::' |
|
// prefix. The 'typename' is required to satisfy the compiler. |
|
typename TestFixture::List values; |
|
|
|
values.push_back(n); |
|
... |
|
} |
|
|
|
TYPED_TEST(FooTest, HasPropertyA) { ... } |
|
``` |
|
|
|
You can see [sample6_unittest.cc] for a complete example. |
|
|
|
[sample6_unittest.cc]: https://github.com/google/googletest/blob/main/googletest/samples/sample6_unittest.cc "Typed Test example" |
|
|
|
## Type-Parameterized Tests |
|
|
|
*Type-parameterized tests* are like typed tests, except that they don't require |
|
you to know the list of types ahead of time. Instead, you can define the test |
|
logic first and instantiate it with different type lists later. You can even |
|
instantiate it more than once in the same program. |
|
|
|
If you are designing an interface or concept, you can define a suite of |
|
type-parameterized tests to verify properties that any valid implementation of |
|
the interface/concept should have. Then, the author of each implementation can |
|
just instantiate the test suite with their type to verify that it conforms to |
|
the requirements, without having to write similar tests repeatedly. Here's an |
|
example: |
|
|
|
First, define a fixture class template, as we did with typed tests: |
|
|
|
```c++ |
|
template <typename T> |
|
class FooTest : public testing::Test { |
|
void DoSomethingInteresting(); |
|
... |
|
}; |
|
``` |
|
|
|
Next, declare that you will define a type-parameterized test suite: |
|
|
|
```c++ |
|
TYPED_TEST_SUITE_P(FooTest); |
|
``` |
|
|
|
Then, use `TYPED_TEST_P()` to define a type-parameterized test. You can repeat |
|
this as many times as you want: |
|
|
|
```c++ |
|
TYPED_TEST_P(FooTest, DoesBlah) { |
|
// Inside a test, refer to TypeParam to get the type parameter. |
|
TypeParam n = 0; |
|
|
|
// You will need to use `this` explicitly to refer to fixture members. |
|
this->DoSomethingInteresting() |
|
... |
|
} |
|
|
|
TYPED_TEST_P(FooTest, HasPropertyA) { ... } |
|
``` |
|
|
|
Now the tricky part: you need to register all test patterns using the |
|
`REGISTER_TYPED_TEST_SUITE_P` macro before you can instantiate them. The first |
|
argument of the macro is the test suite name; the rest are the names of the |
|
tests in this test suite: |
|
|
|
```c++ |
|
REGISTER_TYPED_TEST_SUITE_P(FooTest, |
|
DoesBlah, HasPropertyA); |
|
``` |
|
|
|
Finally, you are free to instantiate the pattern with the types you want. If you |
|
put the above code in a header file, you can `#include` it in multiple C++ |
|
source files and instantiate it multiple times. |
|
|
|
```c++ |
|
using MyTypes = ::testing::Types<char, int, unsigned int>; |
|
INSTANTIATE_TYPED_TEST_SUITE_P(My, FooTest, MyTypes); |
|
``` |
|
|
|
To distinguish different instances of the pattern, the first argument to the |
|
`INSTANTIATE_TYPED_TEST_SUITE_P` macro is a prefix that will be added to the |
|
actual test suite name. Remember to pick unique prefixes for different |
|
instances. |
|
|
|
In the special case where the type list contains only one type, you can write |
|
that type directly without `::testing::Types<...>`, like this: |
|
|
|
```c++ |
|
INSTANTIATE_TYPED_TEST_SUITE_P(My, FooTest, int); |
|
``` |
|
|
|
You can see [sample6_unittest.cc] for a complete example. |
|
|
|
## Testing Private Code |
|
|
|
If you change your software's internal implementation, your tests should not |
|
break as long as the change is not observable by users. Therefore, **per the |
|
black-box testing principle, most of the time you should test your code through |
|
its public interfaces.** |
|
|
|
**If you still find yourself needing to test internal implementation code, |
|
consider if there's a better design.** The desire to test internal |
|
implementation is often a sign that the class is doing too much. Consider |
|
extracting an implementation class, and testing it. Then use that implementation |
|
class in the original class. |
|
|
|
If you absolutely have to test non-public interface code though, you can. There |
|
are two cases to consider: |
|
|
|
* Static functions ( *not* the same as static member functions!) or unnamed |
|
namespaces, and |
|
* Private or protected class members |
|
|
|
To test them, we use the following special techniques: |
|
|
|
* Both static functions and definitions/declarations in an unnamed namespace |
|
are only visible within the same translation unit. To test them, you can |
|
`#include` the entire `.cc` file being tested in your `*_test.cc` file. |
|
(#including `.cc` files is not a good way to reuse code - you should not do |
|
this in production code!) |
|
|
|
However, a better approach is to move the private code into the |
|
`foo::internal` namespace, where `foo` is the namespace your project |
|
normally uses, and put the private declarations in a `*-internal.h` file. |
|
Your production `.cc` files and your tests are allowed to include this |
|
internal header, but your clients are not. This way, you can fully test your |
|
internal implementation without leaking it to your clients. |
|
|
|
* Private class members are only accessible from within the class or by |
|
friends. To access a class' private members, you can declare your test |
|
fixture as a friend to the class and define accessors in your fixture. Tests |
|
using the fixture can then access the private members of your production |
|
class via the accessors in the fixture. Note that even though your fixture |
|
is a friend to your production class, your tests are not automatically |
|
friends to it, as they are technically defined in sub-classes of the |
|
fixture. |
|
|
|
Another way to test private members is to refactor them into an |
|
implementation class, which is then declared in a `*-internal.h` file. Your |
|
clients aren't allowed to include this header but your tests can. Such is |
|
called the |
|
[Pimpl](https://www.gamedev.net/articles/programming/general-and-gameplay-programming/the-c-pimpl-r1794/) |
|
(Private Implementation) idiom. |
|
|
|
Or, you can declare an individual test as a friend of your class by adding |
|
this line in the class body: |
|
|
|
```c++ |
|
FRIEND_TEST(TestSuiteName, TestName); |
|
``` |
|
|
|
For example, |
|
|
|
```c++ |
|
// foo.h |
|
class Foo { |
|
... |
|
private: |
|
FRIEND_TEST(FooTest, BarReturnsZeroOnNull); |
|
|
|
int Bar(void* x); |
|
}; |
|
|
|
// foo_test.cc |
|
... |
|
TEST(FooTest, BarReturnsZeroOnNull) { |
|
Foo foo; |
|
EXPECT_EQ(foo.Bar(NULL), 0); // Uses Foo's private member Bar(). |
|
} |
|
``` |
|
|
|
Pay special attention when your class is defined in a namespace. If you want |
|
your test fixtures and tests to be friends of your class, then they must be |
|
defined in the exact same namespace (no anonymous or inline namespaces). |
|
|
|
For example, if the code to be tested looks like: |
|
|
|
```c++ |
|
namespace my_namespace { |
|
|
|
class Foo { |
|
friend class FooTest; |
|
FRIEND_TEST(FooTest, Bar); |
|
FRIEND_TEST(FooTest, Baz); |
|
... definition of the class Foo ... |
|
}; |
|
|
|
} // namespace my_namespace |
|
``` |
|
|
|
Your test code should be something like: |
|
|
|
```c++ |
|
namespace my_namespace { |
|
|
|
class FooTest : public testing::Test { |
|
protected: |
|
... |
|
}; |
|
|
|
TEST_F(FooTest, Bar) { ... } |
|
TEST_F(FooTest, Baz) { ... } |
|
|
|
} // namespace my_namespace |
|
``` |
|
|
|
## "Catching" Failures |
|
|
|
If you are building a testing utility on top of GoogleTest, you'll want to test |
|
your utility. What framework would you use to test it? GoogleTest, of course. |
|
|
|
The challenge is to verify that your testing utility reports failures correctly. |
|
In frameworks that report a failure by throwing an exception, you could catch |
|
the exception and assert on it. But GoogleTest doesn't use exceptions, so how do |
|
we test that a piece of code generates an expected failure? |
|
|
|
`"gtest/gtest-spi.h"` contains some constructs to do this. |
|
After #including this header, you can use |
|
|
|
```c++ |
|
EXPECT_FATAL_FAILURE(statement, substring); |
|
``` |
|
|
|
to assert that `statement` generates a fatal (e.g. `ASSERT_*`) failure in the |
|
current thread whose message contains the given `substring`, or use |
|
|
|
```c++ |
|
EXPECT_NONFATAL_FAILURE(statement, substring); |
|
``` |
|
|
|
if you are expecting a non-fatal (e.g. `EXPECT_*`) failure. |
|
|
|
Only failures in the current thread are checked to determine the result of this |
|
type of expectations. If `statement` creates new threads, failures in these |
|
threads are also ignored. If you want to catch failures in other threads as |
|
well, use one of the following macros instead: |
|
|
|
```c++ |
|
EXPECT_FATAL_FAILURE_ON_ALL_THREADS(statement, substring); |
|
EXPECT_NONFATAL_FAILURE_ON_ALL_THREADS(statement, substring); |
|
``` |
|
|
|
{: .callout .note} |
|
NOTE: Assertions from multiple threads are currently not supported on Windows. |
|
|
|
For technical reasons, there are some caveats: |
|
|
|
1. You cannot stream a failure message to either macro. |
|
|
|
2. `statement` in `EXPECT_FATAL_FAILURE{_ON_ALL_THREADS}()` cannot reference |
|
local non-static variables or non-static members of `this` object. |
|
|
|
3. `statement` in `EXPECT_FATAL_FAILURE{_ON_ALL_THREADS}()` cannot return a |
|
value. |
|
|
|
## Registering tests programmatically |
|
|
|
The `TEST` macros handle the vast majority of all use cases, but there are few |
|
where runtime registration logic is required. For those cases, the framework |
|
provides the `::testing::RegisterTest` that allows callers to register arbitrary |
|
tests dynamically. |
|
|
|
This is an advanced API only to be used when the `TEST` macros are insufficient. |
|
The macros should be preferred when possible, as they avoid most of the |
|
complexity of calling this function. |
|
|
|
It provides the following signature: |
|
|
|
```c++ |
|
template <typename Factory> |
|
TestInfo* RegisterTest(const char* test_suite_name, const char* test_name, |
|
const char* type_param, const char* value_param, |
|
const char* file, int line, Factory factory); |
|
``` |
|
|
|
The `factory` argument is a factory callable (move-constructible) object or |
|
function pointer that creates a new instance of the Test object. It handles |
|
ownership to the caller. The signature of the callable is `Fixture*()`, where |
|
`Fixture` is the test fixture class for the test. All tests registered with the |
|
same `test_suite_name` must return the same fixture type. This is checked at |
|
runtime. |
|
|
|
The framework will infer the fixture class from the factory and will call the |
|
`SetUpTestSuite` and `TearDownTestSuite` for it. |
|
|
|
Must be called before `RUN_ALL_TESTS()` is invoked, otherwise behavior is |
|
undefined. |
|
|
|
Use case example: |
|
|
|
```c++ |
|
class MyFixture : public testing::Test { |
|
public: |
|
// All of these optional, just like in regular macro usage. |
|
static void SetUpTestSuite() { ... } |
|
static void TearDownTestSuite() { ... } |
|
void SetUp() override { ... } |
|
void TearDown() override { ... } |
|
}; |
|
|
|
class MyTest : public MyFixture { |
|
public: |
|
explicit MyTest(int data) : data_(data) {} |
|
void TestBody() override { ... } |
|
|
|
private: |
|
int data_; |
|
}; |
|
|
|
void RegisterMyTests(const std::vector<int>& values) { |
|
for (int v : values) { |
|
testing::RegisterTest( |
|
"MyFixture", ("Test" + std::to_string(v)).c_str(), nullptr, |
|
std::to_string(v).c_str(), |
|
__FILE__, __LINE__, |
|
// Important to use the fixture type as the return type here. |
|
[=]() -> MyFixture* { return new MyTest(v); }); |
|
} |
|
} |
|
... |
|
int main(int argc, char** argv) { |
|
testing::InitGoogleTest(&argc, argv); |
|
std::vector<int> values_to_test = LoadValuesFromConfig(); |
|
RegisterMyTests(values_to_test); |
|
... |
|
return RUN_ALL_TESTS(); |
|
} |
|
``` |
|
|
|
## Getting the Current Test's Name |
|
|
|
Sometimes a function may need to know the name of the currently running test. |
|
For example, you may be using the `SetUp()` method of your test fixture to set |
|
the golden file name based on which test is running. The |
|
[`TestInfo`](reference/testing.md#TestInfo) class has this information. |
|
|
|
To obtain a `TestInfo` object for the currently running test, call |
|
`current_test_info()` on the [`UnitTest`](reference/testing.md#UnitTest) |
|
singleton object: |
|
|
|
```c++ |
|
// Gets information about the currently running test. |
|
// Do NOT delete the returned object - it's managed by the UnitTest class. |
|
const testing::TestInfo* const test_info = |
|
testing::UnitTest::GetInstance()->current_test_info(); |
|
|
|
printf("We are in test %s of test suite %s.\n", |
|
test_info->name(), |
|
test_info->test_suite_name()); |
|
``` |
|
|
|
`current_test_info()` returns a null pointer if no test is running. In |
|
particular, you cannot find the test suite name in `SetUpTestSuite()`, |
|
`TearDownTestSuite()` (where you know the test suite name implicitly), or |
|
functions called from them. |
|
|
|
## Extending GoogleTest by Handling Test Events |
|
|
|
GoogleTest provides an **event listener API** to let you receive notifications |
|
about the progress of a test program and test failures. The events you can |
|
listen to include the start and end of the test program, a test suite, or a test |
|
method, among others. You may use this API to augment or replace the standard |
|
console output, replace the XML output, or provide a completely different form |
|
of output, such as a GUI or a database. You can also use test events as |
|
checkpoints to implement a resource leak checker, for example. |
|
|
|
### Defining Event Listeners |
|
|
|
To define a event listener, you subclass either |
|
[`testing::TestEventListener`](reference/testing.md#TestEventListener) or |
|
[`testing::EmptyTestEventListener`](reference/testing.md#EmptyTestEventListener) |
|
The former is an (abstract) interface, where *each pure virtual method can be |
|
overridden to handle a test event* (For example, when a test starts, the |
|
`OnTestStart()` method will be called.). The latter provides an empty |
|
implementation of all methods in the interface, such that a subclass only needs |
|
to override the methods it cares about. |
|
|
|
When an event is fired, its context is passed to the handler function as an |
|
argument. The following argument types are used: |
|
|
|
* UnitTest reflects the state of the entire test program, |
|
* TestSuite has information about a test suite, which can contain one or more |
|
tests, |
|
* TestInfo contains the state of a test, and |
|
* TestPartResult represents the result of a test assertion. |
|
|
|
An event handler function can examine the argument it receives to find out |
|
interesting information about the event and the test program's state. |
|
|
|
Here's an example: |
|
|
|
```c++ |
|
class MinimalistPrinter : public testing::EmptyTestEventListener { |
|
// Called before a test starts. |
|
void OnTestStart(const testing::TestInfo& test_info) override { |
|
printf("*** Test %s.%s starting.\n", |
|
test_info.test_suite_name(), test_info.name()); |
|
} |
|
|
|
// Called after a failed assertion or a SUCCESS(). |
|
void OnTestPartResult(const testing::TestPartResult& test_part_result) override { |
|
printf("%s in %s:%d\n%s\n", |
|
test_part_result.failed() ? "*** Failure" : "Success", |
|
test_part_result.file_name(), |
|
test_part_result.line_number(), |
|
test_part_result.summary()); |
|
} |
|
|
|
// Called after a test ends. |
|
void OnTestEnd(const testing::TestInfo& test_info) override { |
|
printf("*** Test %s.%s ending.\n", |
|
test_info.test_suite_name(), test_info.name()); |
|
} |
|
}; |
|
``` |
|
|
|
### Using Event Listeners |
|
|
|
To use the event listener you have defined, add an instance of it to the |
|
GoogleTest event listener list (represented by class |
|
[`TestEventListeners`](reference/testing.md#TestEventListeners) - note the "s" |
|
at the end of the name) in your `main()` function, before calling |
|
`RUN_ALL_TESTS()`: |
|
|
|
```c++ |
|
int main(int argc, char** argv) { |
|
testing::InitGoogleTest(&argc, argv); |
|
// Gets hold of the event listener list. |
|
testing::TestEventListeners& listeners = |
|
testing::UnitTest::GetInstance()->listeners(); |
|
// Adds a listener to the end. GoogleTest takes the ownership. |
|
listeners.Append(new MinimalistPrinter); |
|
return RUN_ALL_TESTS(); |
|
} |
|
``` |
|
|
|
There's only one problem: the default test result printer is still in effect, so |
|
its output will mingle with the output from your minimalist printer. To suppress |
|
the default printer, just release it from the event listener list and delete it. |
|
You can do so by adding one line: |
|
|
|
```c++ |
|
... |
|
delete listeners.Release(listeners.default_result_printer()); |
|
listeners.Append(new MinimalistPrinter); |
|
return RUN_ALL_TESTS(); |
|
``` |
|
|
|
Now, sit back and enjoy a completely different output from your tests. For more |
|
details, see [sample9_unittest.cc]. |
|
|
|
[sample9_unittest.cc]: https://github.com/google/googletest/blob/main/googletest/samples/sample9_unittest.cc "Event listener example" |
|
|
|
You may append more than one listener to the list. When an `On*Start()` or |
|
`OnTestPartResult()` event is fired, the listeners will receive it in the order |
|
they appear in the list (since new listeners are added to the end of the list, |
|
the default text printer and the default XML generator will receive the event |
|
first). An `On*End()` event will be received by the listeners in the *reverse* |
|
order. This allows output by listeners added later to be framed by output from |
|
listeners added earlier. |
|
|
|
### Generating Failures in Listeners |
|
|
|
You may use failure-raising macros (`EXPECT_*()`, `ASSERT_*()`, `FAIL()`, etc) |
|
when processing an event. There are some restrictions: |
|
|
|
1. You cannot generate any failure in `OnTestPartResult()` (otherwise it will |
|
cause `OnTestPartResult()` to be called recursively). |
|
2. A listener that handles `OnTestPartResult()` is not allowed to generate any |
|
failure. |
|
|
|
When you add listeners to the listener list, you should put listeners that |
|
handle `OnTestPartResult()` *before* listeners that can generate failures. This |
|
ensures that failures generated by the latter are attributed to the right test |
|
by the former. |
|
|
|
See [sample10_unittest.cc] for an example of a failure-raising listener. |
|
|
|
[sample10_unittest.cc]: https://github.com/google/googletest/blob/main/googletest/samples/sample10_unittest.cc "Failure-raising listener example" |
|
|
|
## Running Test Programs: Advanced Options |
|
|
|
GoogleTest test programs are ordinary executables. Once built, you can run them |
|
directly and affect their behavior via the following environment variables |
|
and/or command line flags. For the flags to work, your programs must call |
|
`::testing::InitGoogleTest()` before calling `RUN_ALL_TESTS()`. |
|
|
|
To see a list of supported flags and their usage, please run your test program |
|
with the `--help` flag. |
|
|
|
If an option is specified both by an environment variable and by a flag, the |
|
latter takes precedence. |
|
|
|
### Selecting Tests |
|
|
|
#### Listing Test Names |
|
|
|
Sometimes it is necessary to list the available tests in a program before |
|
running them so that a filter may be applied if needed. Including the flag |
|
`--gtest_list_tests` overrides all other flags and lists tests in the following |
|
format: |
|
|
|
```none |
|
TestSuite1. |
|
TestName1 |
|
TestName2 |
|
TestSuite2. |
|
TestName |
|
``` |
|
|
|
None of the tests listed are actually run if the flag is provided. There is no |
|
corresponding environment variable for this flag. |
|
|
|
#### Running a Subset of the Tests |
|
|
|
By default, a GoogleTest program runs all tests the user has defined. Sometimes, |
|
you want to run only a subset of the tests (e.g. for debugging or quickly |
|
verifying a change). If you set the `GTEST_FILTER` environment variable or the |
|
`--gtest_filter` flag to a filter string, GoogleTest will only run the tests |
|
whose full names (in the form of `TestSuiteName.TestName`) match the filter. |
|
|
|
The format of a filter is a '`:`'-separated list of wildcard patterns (called |
|
the *positive patterns*) optionally followed by a '`-`' and another |
|
'`:`'-separated pattern list (called the *negative patterns*). A test matches |
|
the filter if and only if it matches any of the positive patterns but does not |
|
match any of the negative patterns. |
|
|
|
A pattern may contain `'*'` (matches any string) or `'?'` (matches any single |
|
character). For convenience, the filter `'*-NegativePatterns'` can be also |
|
written as `'-NegativePatterns'`. |
|
|
|
For example: |
|
|
|
* `./foo_test` Has no flag, and thus runs all its tests. |
|
* `./foo_test --gtest_filter=*` Also runs everything, due to the single |
|
match-everything `*` value. |
|
* `./foo_test --gtest_filter=FooTest.*` Runs everything in test suite |
|
`FooTest` . |
|
* `./foo_test --gtest_filter=*Null*:*Constructor*` Runs any test whose full |
|
name contains either `"Null"` or `"Constructor"` . |
|
* `./foo_test --gtest_filter=-*DeathTest.*` Runs all non-death tests. |
|
* `./foo_test --gtest_filter=FooTest.*-FooTest.Bar` Runs everything in test |
|
suite `FooTest` except `FooTest.Bar`. |
|
* `./foo_test --gtest_filter=FooTest.*:BarTest.*-FooTest.Bar:BarTest.Foo` Runs |
|
everything in test suite `FooTest` except `FooTest.Bar` and everything in |
|
test suite `BarTest` except `BarTest.Foo`. |
|
|
|
#### Stop test execution upon first failure |
|
|
|
By default, a GoogleTest program runs all tests the user has defined. In some |
|
cases (e.g. iterative test development & execution) it may be desirable stop |
|
test execution upon first failure (trading improved latency for completeness). |
|
If `GTEST_FAIL_FAST` environment variable or `--gtest_fail_fast` flag is set, |
|
the test runner will stop execution as soon as the first test failure is found. |
|
|
|
#### Temporarily Disabling Tests |
|
|
|
If you have a broken test that you cannot fix right away, you can add the |
|
`DISABLED_` prefix to its name. This will exclude it from execution. This is |
|
better than commenting out the code or using `#if 0`, as disabled tests are |
|
still compiled (and thus won't rot). |
|
|
|
If you need to disable all tests in a test suite, you can either add `DISABLED_` |
|
to the front of the name of each test, or alternatively add it to the front of |
|
the test suite name. |
|
|
|
For example, the following tests won't be run by GoogleTest, even though they |
|
will still be compiled: |
|
|
|
```c++ |
|
// Tests that Foo does Abc. |
|
TEST(FooTest, DISABLED_DoesAbc) { ... } |
|
|
|
class DISABLED_BarTest : public testing::Test { ... }; |
|
|
|
// Tests that Bar does Xyz. |
|
TEST_F(DISABLED_BarTest, DoesXyz) { ... } |
|
``` |
|
|
|
{: .callout .note} |
|
NOTE: This feature should only be used for temporary pain-relief. You still have |
|
to fix the disabled tests at a later date. As a reminder, GoogleTest will print |
|
a banner warning you if a test program contains any disabled tests. |
|
|
|
{: .callout .tip} |
|
TIP: You can easily count the number of disabled tests you have using |
|
`grep`. This number can be used as a metric for |
|
improving your test quality. |
|
|
|
#### Temporarily Enabling Disabled Tests |
|
|
|
To include disabled tests in test execution, just invoke the test program with |
|
the `--gtest_also_run_disabled_tests` flag or set the |
|
`GTEST_ALSO_RUN_DISABLED_TESTS` environment variable to a value other than `0`. |
|
You can combine this with the `--gtest_filter` flag to further select which |
|
disabled tests to run. |
|
|
|
### Repeating the Tests |
|
|
|
Once in a while you'll run into a test whose result is hit-or-miss. Perhaps it |
|
will fail only 1% of the time, making it rather hard to reproduce the bug under |
|
a debugger. This can be a major source of frustration. |
|
|
|
The `--gtest_repeat` flag allows you to repeat all (or selected) test methods in |
|
a program many times. Hopefully, a flaky test will eventually fail and give you |
|
a chance to debug. Here's how to use it: |
|
|
|
```none |
|
$ foo_test --gtest_repeat=1000 |
|
Repeat foo_test 1000 times and don't stop at failures. |
|
|
|
$ foo_test --gtest_repeat=-1 |
|
A negative count means repeating forever. |
|
|
|
$ foo_test --gtest_repeat=1000 --gtest_break_on_failure |
|
Repeat foo_test 1000 times, stopping at the first failure. This |
|
is especially useful when running under a debugger: when the test |
|
fails, it will drop into the debugger and you can then inspect |
|
variables and stacks. |
|
|
|
$ foo_test --gtest_repeat=1000 --gtest_filter=FooBar.* |
|
Repeat the tests whose name matches the filter 1000 times. |
|
``` |
|
|
|
If your test program contains |
|
[global set-up/tear-down](#global-set-up-and-tear-down) code, it will be |
|
repeated in each iteration as well, as the flakiness may be in it. To avoid |
|
repeating global set-up/tear-down, specify |
|
`--gtest_recreate_environments_when_repeating=false`{.nowrap}. |
|
|
|
You can also specify the repeat count by setting the `GTEST_REPEAT` environment |
|
variable. |
|
|
|
### Shuffling the Tests |
|
|
|
You can specify the `--gtest_shuffle` flag (or set the `GTEST_SHUFFLE` |
|
environment variable to `1`) to run the tests in a program in a random order. |
|
This helps to reveal bad dependencies between tests. |
|
|
|
By default, GoogleTest uses a random seed calculated from the current time. |
|
Therefore you'll get a different order every time. The console output includes |
|
the random seed value, such that you can reproduce an order-related test failure |
|
later. To specify the random seed explicitly, use the `--gtest_random_seed=SEED` |
|
flag (or set the `GTEST_RANDOM_SEED` environment variable), where `SEED` is an |
|
integer in the range [0, 99999]. The seed value 0 is special: it tells |
|
GoogleTest to do the default behavior of calculating the seed from the current |
|
time. |
|
|
|
If you combine this with `--gtest_repeat=N`, GoogleTest will pick a different |
|
random seed and re-shuffle the tests in each iteration. |
|
|
|
### Distributing Test Functions to Multiple Machines |
|
|
|
If you have more than one machine you can use to run a test program, you might |
|
want to run the test functions in parallel and get the result faster. We call |
|
this technique *sharding*, where each machine is called a *shard*. |
|
|
|
GoogleTest is compatible with test sharding. To take advantage of this feature, |
|
your test runner (not part of GoogleTest) needs to do the following: |
|
|
|
1. Allocate a number of machines (shards) to run the tests. |
|
1. On each shard, set the `GTEST_TOTAL_SHARDS` environment variable to the total |
|
number of shards. It must be the same for all shards. |
|
1. On each shard, set the `GTEST_SHARD_INDEX` environment variable to the index |
|
of the shard. Different shards must be assigned different indices, which |
|
must be in the range `[0, GTEST_TOTAL_SHARDS - 1]`. |
|
1. Run the same test program on all shards. When GoogleTest sees the above two |
|
environment variables, it will select a subset of the test functions to run. |
|
Across all shards, each test function in the program will be run exactly |
|
once. |
|
1. Wait for all shards to finish, then collect and report the results. |
|
|
|
Your project may have tests that were written without GoogleTest and thus don't |
|
understand this protocol. In order for your test runner to figure out which test |
|
supports sharding, it can set the environment variable `GTEST_SHARD_STATUS_FILE` |
|
to a non-existent file path. If a test program supports sharding, it will create |
|
this file to acknowledge that fact; otherwise it will not create it. The actual |
|
contents of the file are not important at this time, although we may put some |
|
useful information in it in the future. |
|
|
|
Here's an example to make it clear. Suppose you have a test program `foo_test` |
|
that contains the following 5 test functions: |
|
|
|
``` |
|
TEST(A, V) |
|
TEST(A, W) |
|
TEST(B, X) |
|
TEST(B, Y) |
|
TEST(B, Z) |
|
``` |
|
|
|
Suppose you have 3 machines at your disposal. To run the test functions in |
|
parallel, you would set `GTEST_TOTAL_SHARDS` to 3 on all machines, and set |
|
`GTEST_SHARD_INDEX` to 0, 1, and 2 on the machines respectively. Then you would |
|
run the same `foo_test` on each machine. |
|
|
|
GoogleTest reserves the right to change how the work is distributed across the |
|
shards, but here's one possible scenario: |
|
|
|
* Machine #0 runs `A.V` and `B.X`. |
|
* Machine #1 runs `A.W` and `B.Y`. |
|
* Machine #2 runs `B.Z`. |
|
|
|
### Controlling Test Output |
|
|
|
#### Colored Terminal Output |
|
|
|
GoogleTest can use colors in its terminal output to make it easier to spot the |
|
important information: |
|
|
|
<pre>... |
|
<font color="green">[----------]</font> 1 test from FooTest |
|
<font color="green">[ RUN ]</font> FooTest.DoesAbc |
|
<font color="green">[ OK ]</font> FooTest.DoesAbc |
|
<font color="green">[----------]</font> 2 tests from BarTest |
|
<font color="green">[ RUN ]</font> BarTest.HasXyzProperty |
|
<font color="green">[ OK ]</font> BarTest.HasXyzProperty |
|
<font color="green">[ RUN ]</font> BarTest.ReturnsTrueOnSuccess |
|
... some error messages ... |
|
<font color="red">[ FAILED ]</font> BarTest.ReturnsTrueOnSuccess |
|
... |
|
<font color="green">[==========]</font> 30 tests from 14 test suites ran. |
|
<font color="green">[ PASSED ]</font> 28 tests. |
|
<font color="red">[ FAILED ]</font> 2 tests, listed below: |
|
<font color="red">[ FAILED ]</font> BarTest.ReturnsTrueOnSuccess |
|
<font color="red">[ FAILED ]</font> AnotherTest.DoesXyz |
|
|
|
2 FAILED TESTS |
|
</pre> |
|
|
|
You can set the `GTEST_COLOR` environment variable or the `--gtest_color` |
|
command line flag to `yes`, `no`, or `auto` (the default) to enable colors, |
|
disable colors, or let GoogleTest decide. When the value is `auto`, GoogleTest |
|
will use colors if and only if the output goes to a terminal and (on non-Windows |
|
platforms) the `TERM` environment variable is set to `xterm` or `xterm-color`. |
|
|
|
#### Suppressing test passes |
|
|
|
By default, GoogleTest prints 1 line of output for each test, indicating if it |
|
passed or failed. To show only test failures, run the test program with |
|
`--gtest_brief=1`, or set the GTEST_BRIEF environment variable to `1`. |
|
|
|
#### Suppressing the Elapsed Time |
|
|
|
By default, GoogleTest prints the time it takes to run each test. To disable |
|
that, run the test program with the `--gtest_print_time=0` command line flag, or |
|
set the GTEST_PRINT_TIME environment variable to `0`. |
|
|
|
#### Suppressing UTF-8 Text Output |
|
|
|
In case of assertion failures, GoogleTest prints expected and actual values of |
|
type `string` both as hex-encoded strings as well as in readable UTF-8 text if |
|
they contain valid non-ASCII UTF-8 characters. If you want to suppress the UTF-8 |
|
text because, for example, you don't have an UTF-8 compatible output medium, run |
|
the test program with `--gtest_print_utf8=0` or set the `GTEST_PRINT_UTF8` |
|
environment variable to `0`. |
|
|
|
#### Generating an XML Report |
|
|
|
GoogleTest can emit a detailed XML report to a file in addition to its normal |
|
textual output. The report contains the duration of each test, and thus can help |
|
you identify slow tests. |
|
|
|
To generate the XML report, set the `GTEST_OUTPUT` environment variable or the |
|
`--gtest_output` flag to the string `"xml:path_to_output_file"`, which will |
|
create the file at the given location. You can also just use the string `"xml"`, |
|
in which case the output can be found in the `test_detail.xml` file in the |
|
current directory. |
|
|
|
If you specify a directory (for example, `"xml:output/directory/"` on Linux or |
|
`"xml:output\directory\"` on Windows), GoogleTest will create the XML file in |
|
that directory, named after the test executable (e.g. `foo_test.xml` for test |
|
program `foo_test` or `foo_test.exe`). If the file already exists (perhaps left |
|
over from a previous run), GoogleTest will pick a different name (e.g. |
|
`foo_test_1.xml`) to avoid overwriting it. |
|
|
|
The report is based on the `junitreport` Ant task. Since that format was |
|
originally intended for Java, a little interpretation is required to make it |
|
apply to GoogleTest tests, as shown here: |
|
|
|
```xml |
|
<testsuites name="AllTests" ...> |
|
<testsuite name="test_case_name" ...> |
|
<testcase name="test_name" ...> |
|
<failure message="..."/> |
|
<failure message="..."/> |
|
<failure message="..."/> |
|
</testcase> |
|
</testsuite> |
|
</testsuites> |
|
``` |
|
|
|
* The root `<testsuites>` element corresponds to the entire test program. |
|
* `<testsuite>` elements correspond to GoogleTest test suites. |
|
* `<testcase>` elements correspond to GoogleTest test functions. |
|
|
|
For instance, the following program |
|
|
|
```c++ |
|
TEST(MathTest, Addition) { ... } |
|
TEST(MathTest, Subtraction) { ... } |
|
TEST(LogicTest, NonContradiction) { ... } |
|
``` |
|
|
|
could generate this report: |
|
|
|
```xml |
|
<?xml version="1.0" encoding="UTF-8"?> |
|
<testsuites tests="3" failures="1" errors="0" time="0.035" timestamp="2011-10-31T18:52:42" name="AllTests"> |
|
<testsuite name="MathTest" tests="2" failures="1" errors="0" time="0.015"> |
|
<testcase name="Addition" file="test.cpp" line="1" status="run" time="0.007" classname=""> |
|
<failure message="Value of: add(1, 1)
 Actual: 3
Expected: 2" type="">...</failure> |
|
<failure message="Value of: add(1, -1)
 Actual: 1
Expected: 0" type="">...</failure> |
|
</testcase> |
|
<testcase name="Subtraction" file="test.cpp" line="2" status="run" time="0.005" classname=""> |
|
</testcase> |
|
</testsuite> |
|
<testsuite name="LogicTest" tests="1" failures="0" errors="0" time="0.005"> |
|
<testcase name="NonContradiction" file="test.cpp" line="3" status="run" time="0.005" classname=""> |
|
</testcase> |
|
</testsuite> |
|
</testsuites> |
|
``` |
|
|
|
Things to note: |
|
|
|
* The `tests` attribute of a `<testsuites>` or `<testsuite>` element tells how |
|
many test functions the GoogleTest program or test suite contains, while the |
|
`failures` attribute tells how many of them failed. |
|
|
|
* The `time` attribute expresses the duration of the test, test suite, or |
|
entire test program in seconds. |
|
|
|
* The `timestamp` attribute records the local date and time of the test |
|
execution. |
|
|
|
* The `file` and `line` attributes record the source file location, where the |
|
test was defined. |
|
|
|
* Each `<failure>` element corresponds to a single failed GoogleTest |
|
assertion. |
|
|
|
#### Generating a JSON Report |
|
|
|
GoogleTest can also emit a JSON report as an alternative format to XML. To |
|
generate the JSON report, set the `GTEST_OUTPUT` environment variable or the |
|
`--gtest_output` flag to the string `"json:path_to_output_file"`, which will |
|
create the file at the given location. You can also just use the string |
|
`"json"`, in which case the output can be found in the `test_detail.json` file |
|
in the current directory. |
|
|
|
The report format conforms to the following JSON Schema: |
|
|
|
```json |
|
{ |
|
"$schema": "https://json-schema.org/schema#", |
|
"type": "object", |
|
"definitions": { |
|
"TestCase": { |
|
"type": "object", |
|
"properties": { |
|
"name": { "type": "string" }, |
|
"tests": { "type": "integer" }, |
|
"failures": { "type": "integer" }, |
|
"disabled": { "type": "integer" }, |
|
"time": { "type": "string" }, |
|
"testsuite": { |
|
"type": "array", |
|
"items": { |
|
"$ref": "#/definitions/TestInfo" |
|
} |
|
} |
|
} |
|
}, |
|
"TestInfo": { |
|
"type": "object", |
|
"properties": { |
|
"name": { "type": "string" }, |
|
"file": { "type": "string" }, |
|
"line": { "type": "integer" }, |
|
"status": { |
|
"type": "string", |
|
"enum": ["RUN", "NOTRUN"] |
|
}, |
|
"time": { "type": "string" }, |
|
"classname": { "type": "string" }, |
|
"failures": { |
|
"type": "array", |
|
"items": { |
|
"$ref": "#/definitions/Failure" |
|
} |
|
} |
|
} |
|
}, |
|
"Failure": { |
|
"type": "object", |
|
"properties": { |
|
"failures": { "type": "string" }, |
|
"type": { "type": "string" } |
|
} |
|
} |
|
}, |
|
"properties": { |
|
"tests": { "type": "integer" }, |
|
"failures": { "type": "integer" }, |
|
"disabled": { "type": "integer" }, |
|
"errors": { "type": "integer" }, |
|
"timestamp": { |
|
"type": "string", |
|
"format": "date-time" |
|
}, |
|
"time": { "type": "string" }, |
|
"name": { "type": "string" }, |
|
"testsuites": { |
|
"type": "array", |
|
"items": { |
|
"$ref": "#/definitions/TestCase" |
|
} |
|
} |
|
} |
|
} |
|
``` |
|
|
|
The report uses the format that conforms to the following Proto3 using the |
|
[JSON encoding](https://developers.google.com/protocol-buffers/docs/proto3#json): |
|
|
|
```proto |
|
syntax = "proto3"; |
|
|
|
package googletest; |
|
|
|
import "google/protobuf/timestamp.proto"; |
|
import "google/protobuf/duration.proto"; |
|
|
|
message UnitTest { |
|
int32 tests = 1; |
|
int32 failures = 2; |
|
int32 disabled = 3; |
|
int32 errors = 4; |
|
google.protobuf.Timestamp timestamp = 5; |
|
google.protobuf.Duration time = 6; |
|
string name = 7; |
|
repeated TestCase testsuites = 8; |
|
} |
|
|
|
message TestCase { |
|
string name = 1; |
|
int32 tests = 2; |
|
int32 failures = 3; |
|
int32 disabled = 4; |
|
int32 errors = 5; |
|
google.protobuf.Duration time = 6; |
|
repeated TestInfo testsuite = 7; |
|
} |
|
|
|
message TestInfo { |
|
string name = 1; |
|
string file = 6; |
|
int32 line = 7; |
|
enum Status { |
|
RUN = 0; |
|
NOTRUN = 1; |
|
} |
|
Status status = 2; |
|
google.protobuf.Duration time = 3; |
|
string classname = 4; |
|
message Failure { |
|
string failures = 1; |
|
string type = 2; |
|
} |
|
repeated Failure failures = 5; |
|
} |
|
``` |
|
|
|
For instance, the following program |
|
|
|
```c++ |
|
TEST(MathTest, Addition) { ... } |
|
TEST(MathTest, Subtraction) { ... } |
|
TEST(LogicTest, NonContradiction) { ... } |
|
``` |
|
|
|
could generate this report: |
|
|
|
```json |
|
{ |
|
"tests": 3, |
|
"failures": 1, |
|
"errors": 0, |
|
"time": "0.035s", |
|
"timestamp": "2011-10-31T18:52:42Z", |
|
"name": "AllTests", |
|
"testsuites": [ |
|
{ |
|
"name": "MathTest", |
|
"tests": 2, |
|
"failures": 1, |
|
"errors": 0, |
|
"time": "0.015s", |
|
"testsuite": [ |
|
{ |
|
"name": "Addition", |
|
"file": "test.cpp", |
|
"line": 1, |
|
"status": "RUN", |
|
"time": "0.007s", |
|
"classname": "", |
|
"failures": [ |
|
{ |
|
"message": "Value of: add(1, 1)\n Actual: 3\nExpected: 2", |
|
"type": "" |
|
}, |
|
{ |
|
"message": "Value of: add(1, -1)\n Actual: 1\nExpected: 0", |
|
"type": "" |
|
} |
|
] |
|
}, |
|
{ |
|
"name": "Subtraction", |
|
"file": "test.cpp", |
|
"line": 2, |
|
"status": "RUN", |
|
"time": "0.005s", |
|
"classname": "" |
|
} |
|
] |
|
}, |
|
{ |
|
"name": "LogicTest", |
|
"tests": 1, |
|
"failures": 0, |
|
"errors": 0, |
|
"time": "0.005s", |
|
"testsuite": [ |
|
{ |
|
"name": "NonContradiction", |
|
"file": "test.cpp", |
|
"line": 3, |
|
"status": "RUN", |
|
"time": "0.005s", |
|
"classname": "" |
|
} |
|
] |
|
} |
|
] |
|
} |
|
``` |
|
|
|
{: .callout .important} |
|
IMPORTANT: The exact format of the JSON document is subject to change. |
|
|
|
### Controlling How Failures Are Reported |
|
|
|
#### Detecting Test Premature Exit |
|
|
|
Google Test implements the _premature-exit-file_ protocol for test runners to |
|
catch any kind of unexpected exits of test programs. Upon start, Google Test |
|
creates the file which will be automatically deleted after all work has been |
|
finished. Then, the test runner can check if this file exists. In case the file |
|
remains undeleted, the inspected test has exited prematurely. |
|
|
|
This feature is enabled only if the `TEST_PREMATURE_EXIT_FILE` environment |
|
variable has been set. |
|
|
|
#### Turning Assertion Failures into Break-Points |
|
|
|
When running test programs under a debugger, it's very convenient if the |
|
debugger can catch an assertion failure and automatically drop into interactive |
|
mode. GoogleTest's *break-on-failure* mode supports this behavior. |
|
|
|
To enable it, set the `GTEST_BREAK_ON_FAILURE` environment variable to a value |
|
other than `0`. Alternatively, you can use the `--gtest_break_on_failure` |
|
command line flag. |
|
|
|
#### Disabling Catching Test-Thrown Exceptions |
|
|
|
GoogleTest can be used either with or without exceptions enabled. If a test |
|
throws a C++ exception or (on Windows) a structured exception (SEH), by default |
|
GoogleTest catches it, reports it as a test failure, and continues with the next |
|
test method. This maximizes the coverage of a test run. Also, on Windows an |
|
uncaught exception will cause a pop-up window, so catching the exceptions allows |
|
you to run the tests automatically. |
|
|
|
When debugging the test failures, however, you may instead want the exceptions |
|
to be handled by the debugger, such that you can examine the call stack when an |
|
exception is thrown. To achieve that, set the `GTEST_CATCH_EXCEPTIONS` |
|
environment variable to `0`, or use the `--gtest_catch_exceptions=0` flag when |
|
running the tests. |
|
|
|
### Sanitizer Integration |
|
|
|
The |
|
[Undefined Behavior Sanitizer](https://clang.llvm.org/docs/UndefinedBehaviorSanitizer.html), |
|
[Address Sanitizer](https://github.com/google/sanitizers/wiki/AddressSanitizer), |
|
and |
|
[Thread Sanitizer](https://github.com/google/sanitizers/wiki/ThreadSanitizerCppManual) |
|
all provide weak functions that you can override to trigger explicit failures |
|
when they detect sanitizer errors, such as creating a reference from `nullptr`. |
|
To override these functions, place definitions for them in a source file that |
|
you compile as part of your main binary: |
|
|
|
``` |
|
extern "C" { |
|
void __ubsan_on_report() { |
|
FAIL() << "Encountered an undefined behavior sanitizer error"; |
|
} |
|
void __asan_on_error() { |
|
FAIL() << "Encountered an address sanitizer error"; |
|
} |
|
void __tsan_on_report() { |
|
FAIL() << "Encountered a thread sanitizer error"; |
|
} |
|
} // extern "C" |
|
``` |
|
|
|
After compiling your project with one of the sanitizers enabled, if a particular |
|
test triggers a sanitizer error, GoogleTest will report that it failed.
|
|
|