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579 lines
24 KiB
579 lines
24 KiB
# Googletest Primer
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## Introduction: Why googletest?
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*googletest* helps you write better C++ tests.
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googletest is a testing framework developed by the Testing Technology team with
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Google's specific requirements and constraints in mind. Whether you work on
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Linux, Windows, or a Mac, if you write C++ code, googletest can help you. And it
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supports *any* kind of tests, not just unit tests.
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So what makes a good test, and how does googletest fit in? We believe:
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1. Tests should be *independent* and *repeatable*. It's a pain to debug a test
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that succeeds or fails as a result of other tests. googletest isolates the
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tests by running each of them on a different object. When a test fails,
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googletest allows you to run it in isolation for quick debugging.
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2. Tests should be well *organized* and reflect the structure of the tested
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code. googletest groups related tests into test suites that can share data
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and subroutines. This common pattern is easy to recognize and makes tests
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easy to maintain. Such consistency is especially helpful when people switch
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projects and start to work on a new code base.
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3. Tests should be *portable* and *reusable*. Google has a lot of code that is
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platform-neutral; its tests should also be platform-neutral. googletest
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works on different OSes, with different compilers, with or without
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exceptions, so googletest tests can work with a variety of configurations.
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4. When tests fail, they should provide as much *information* about the problem
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as possible. googletest doesn't stop at the first test failure. Instead, it
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only stops the current test and continues with the next. You can also set up
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tests that report non-fatal failures after which the current test continues.
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Thus, you can detect and fix multiple bugs in a single run-edit-compile
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cycle.
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5. The testing framework should liberate test writers from housekeeping chores
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and let them focus on the test *content*. googletest automatically keeps
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track of all tests defined, and doesn't require the user to enumerate them
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in order to run them.
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6. Tests should be *fast*. With googletest, you can reuse shared resources
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across tests and pay for the set-up/tear-down only once, without making
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tests depend on each other.
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Since googletest is based on the popular xUnit architecture, you'll feel right
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at home if you've used JUnit or PyUnit before. If not, it will take you about 10
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minutes to learn the basics and get started. So let's go!
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## Beware of the nomenclature
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{: .callout .note}
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_Note:_ There might be some confusion arising from different definitions of the
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terms _Test_, _Test Case_ and _Test Suite_, so beware of misunderstanding these.
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Historically, googletest started to use the term _Test Case_ for grouping
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related tests, whereas current publications, including International Software
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Testing Qualifications Board ([ISTQB](http://www.istqb.org/)) materials and
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various textbooks on software quality, use the term
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_[Test Suite][istqb test suite]_ for this.
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The related term _Test_, as it is used in googletest, corresponds to the term
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_[Test Case][istqb test case]_ of ISTQB and others.
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The term _Test_ is commonly of broad enough sense, including ISTQB's definition
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of _Test Case_, so it's not much of a problem here. But the term _Test Case_ as
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was used in Google Test is of contradictory sense and thus confusing.
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googletest recently started replacing the term _Test Case_ with _Test Suite_.
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The preferred API is *TestSuite*. The older TestCase API is being slowly
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deprecated and refactored away.
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So please be aware of the different definitions of the terms:
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Meaning | googletest Term | [ISTQB](http://www.istqb.org/) Term
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:----------------------------------------------------------------------------------- | :---------------------- | :----------------------------------
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Exercise a particular program path with specific input values and verify the results | [TEST()](#simple-tests) | [Test Case][istqb test case]
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[istqb test case]: http://glossary.istqb.org/en/search/test%20case
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[istqb test suite]: http://glossary.istqb.org/en/search/test%20suite
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## Basic Concepts
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When using googletest, you start by writing *assertions*, which are statements
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that check whether a condition is true. An assertion's result can be *success*,
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*nonfatal failure*, or *fatal failure*. If a fatal failure occurs, it aborts the
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current function; otherwise the program continues normally.
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*Tests* use assertions to verify the tested code's behavior. If a test crashes
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or has a failed assertion, then it *fails*; otherwise it *succeeds*.
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A *test suite* contains one or many tests. You should group your tests into test
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suites that reflect the structure of the tested code. When multiple tests in a
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test suite need to share common objects and subroutines, you can put them into a
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*test fixture* class.
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A *test program* can contain multiple test suites.
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We'll now explain how to write a test program, starting at the individual
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assertion level and building up to tests and test suites.
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## Assertions
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googletest assertions are macros that resemble function calls. You test a class
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or function by making assertions about its behavior. When an assertion fails,
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googletest prints the assertion's source file and line number location, along
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with a failure message. You may also supply a custom failure message which will
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be appended to googletest's message.
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The assertions come in pairs that test the same thing but have different effects
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on the current function. `ASSERT_*` versions generate fatal failures when they
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fail, and **abort the current function**. `EXPECT_*` versions generate nonfatal
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failures, which don't abort the current function. Usually `EXPECT_*` are
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preferred, as they allow more than one failure to be reported in a test.
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However, you should use `ASSERT_*` if it doesn't make sense to continue when the
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assertion in question fails.
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Since a failed `ASSERT_*` returns from the current function immediately,
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possibly skipping clean-up code that comes after it, it may cause a space leak.
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Depending on the nature of the leak, it may or may not be worth fixing - so keep
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this in mind if you get a heap checker error in addition to assertion errors.
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To provide a custom failure message, simply stream it into the macro using the
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`<<` operator or a sequence of such operators. An example:
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```c++
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ASSERT_EQ(x.size(), y.size()) << "Vectors x and y are of unequal length";
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for (int i = 0; i < x.size(); ++i) {
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EXPECT_EQ(x[i], y[i]) << "Vectors x and y differ at index " << i;
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}
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```
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Anything that can be streamed to an `ostream` can be streamed to an assertion
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macro--in particular, C strings and `string` objects. If a wide string
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(`wchar_t*`, `TCHAR*` in `UNICODE` mode on Windows, or `std::wstring`) is
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streamed to an assertion, it will be translated to UTF-8 when printed.
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### Basic Assertions
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These assertions do basic true/false condition testing.
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Fatal assertion | Nonfatal assertion | Verifies
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-------------------------- | -------------------------- | --------------------
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`ASSERT_TRUE(condition);` | `EXPECT_TRUE(condition);` | `condition` is true
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`ASSERT_FALSE(condition);` | `EXPECT_FALSE(condition);` | `condition` is false
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Remember, when they fail, `ASSERT_*` yields a fatal failure and returns from the
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current function, while `EXPECT_*` yields a nonfatal failure, allowing the
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function to continue running. In either case, an assertion failure means its
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containing test fails.
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**Availability**: Linux, Windows, Mac.
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### Binary Comparison
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This section describes assertions that compare two values.
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Fatal assertion | Nonfatal assertion | Verifies
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------------------------ | ------------------------ | --------------
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`ASSERT_EQ(val1, val2);` | `EXPECT_EQ(val1, val2);` | `val1 == val2`
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`ASSERT_NE(val1, val2);` | `EXPECT_NE(val1, val2);` | `val1 != val2`
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`ASSERT_LT(val1, val2);` | `EXPECT_LT(val1, val2);` | `val1 < val2`
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`ASSERT_LE(val1, val2);` | `EXPECT_LE(val1, val2);` | `val1 <= val2`
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`ASSERT_GT(val1, val2);` | `EXPECT_GT(val1, val2);` | `val1 > val2`
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`ASSERT_GE(val1, val2);` | `EXPECT_GE(val1, val2);` | `val1 >= val2`
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Value arguments must be comparable by the assertion's comparison operator or
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you'll get a compiler error. We used to require the arguments to support the
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`<<` operator for streaming to an `ostream`, but this is no longer necessary. If
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`<<` is supported, it will be called to print the arguments when the assertion
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fails; otherwise googletest will attempt to print them in the best way it can.
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For more details and how to customize the printing of the arguments, see the
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[documentation](./advanced.md#teaching-googletest-how-to-print-your-values).
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These assertions can work with a user-defined type, but only if you define the
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corresponding comparison operator (e.g., `==` or `<`). Since this is discouraged
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by the Google
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[C++ Style Guide](https://google.github.io/styleguide/cppguide.html#Operator_Overloading),
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you may need to use `ASSERT_TRUE()` or `EXPECT_TRUE()` to assert the equality of
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two objects of a user-defined type.
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However, when possible, `ASSERT_EQ(actual, expected)` is preferred to
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`ASSERT_TRUE(actual == expected)`, since it tells you `actual` and `expected`'s
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values on failure.
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Arguments are always evaluated exactly once. Therefore, it's OK for the
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arguments to have side effects. However, as with any ordinary C/C++ function,
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the arguments' evaluation order is undefined (i.e., the compiler is free to
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choose any order), and your code should not depend on any particular argument
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evaluation order.
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`ASSERT_EQ()` does pointer equality on pointers. If used on two C strings, it
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tests if they are in the same memory location, not if they have the same value.
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Therefore, if you want to compare C strings (e.g. `const char*`) by value, use
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`ASSERT_STREQ()`, which will be described later on. In particular, to assert
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that a C string is `NULL`, use `ASSERT_STREQ(c_string, NULL)`. Consider using
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`ASSERT_EQ(c_string, nullptr)` if c++11 is supported. To compare two `string`
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objects, you should use `ASSERT_EQ`.
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When doing pointer comparisons use `*_EQ(ptr, nullptr)` and `*_NE(ptr, nullptr)`
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instead of `*_EQ(ptr, NULL)` and `*_NE(ptr, NULL)`. This is because `nullptr` is
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typed, while `NULL` is not. See the [FAQ](faq.md) for more details.
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If you're working with floating point numbers, you may want to use the floating
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point variations of some of these macros in order to avoid problems caused by
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rounding. See [Advanced googletest Topics](advanced.md) for details.
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Macros in this section work with both narrow and wide string objects (`string`
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and `wstring`).
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**Availability**: Linux, Windows, Mac.
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**Historical note**: Before February 2016 `*_EQ` had a convention of calling it
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as `ASSERT_EQ(expected, actual)`, so lots of existing code uses this order. Now
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`*_EQ` treats both parameters in the same way.
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### String Comparison
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The assertions in this group compare two **C strings**. If you want to compare
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two `string` objects, use `EXPECT_EQ`, `EXPECT_NE`, and etc instead.
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| Fatal assertion | Nonfatal assertion | Verifies |
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| -------------------------- | ------------------------------ | -------------------------------------------------------- |
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| `ASSERT_STREQ(str1,str2);` | `EXPECT_STREQ(str1,str2);` | the two C strings have the same content |
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| `ASSERT_STRNE(str1,str2);` | `EXPECT_STRNE(str1,str2);` | the two C strings have different contents |
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| `ASSERT_STRCASEEQ(str1,str2);` | `EXPECT_STRCASEEQ(str1,str2);` | the two C strings have the same content, ignoring case |
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| `ASSERT_STRCASENE(str1,str2);` | `EXPECT_STRCASENE(str1,str2);` | the two C strings have different contents, ignoring case |
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Note that "CASE" in an assertion name means that case is ignored. A `NULL`
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pointer and an empty string are considered *different*.
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`*STREQ*` and `*STRNE*` also accept wide C strings (`wchar_t*`). If a comparison
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of two wide strings fails, their values will be printed as UTF-8 narrow strings.
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**Availability**: Linux, Windows, Mac.
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**See also**: For more string comparison tricks (substring, prefix, suffix, and
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regular expression matching, for example), see [this](advanced.md) in the
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Advanced googletest Guide.
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## Simple Tests
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To create a test:
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1. Use the `TEST()` macro to define and name a test function. These are
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ordinary C++ functions that don't return a value.
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2. In this function, along with any valid C++ statements you want to include,
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use the various googletest assertions to check values.
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3. The test's result is determined by the assertions; if any assertion in the
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test fails (either fatally or non-fatally), or if the test crashes, the
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entire test fails. Otherwise, it succeeds.
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```c++
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TEST(TestSuiteName, TestName) {
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... test body ...
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}
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```
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`TEST()` arguments go from general to specific. The *first* argument is the name
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of the test suite, and the *second* argument is the test's name within the test
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suite. Both names must be valid C++ identifiers, and they should not contain
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any underscores (`_`). A test's *full name* consists of its containing test suite and
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its individual name. Tests from different test suites can have the same
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individual name.
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For example, let's take a simple integer function:
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```c++
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int Factorial(int n); // Returns the factorial of n
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```
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A test suite for this function might look like:
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```c++
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// Tests factorial of 0.
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TEST(FactorialTest, HandlesZeroInput) {
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EXPECT_EQ(Factorial(0), 1);
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}
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// Tests factorial of positive numbers.
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TEST(FactorialTest, HandlesPositiveInput) {
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EXPECT_EQ(Factorial(1), 1);
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EXPECT_EQ(Factorial(2), 2);
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EXPECT_EQ(Factorial(3), 6);
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EXPECT_EQ(Factorial(8), 40320);
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}
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```
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googletest groups the test results by test suites, so logically related tests
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should be in the same test suite; in other words, the first argument to their
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`TEST()` should be the same. In the above example, we have two tests,
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`HandlesZeroInput` and `HandlesPositiveInput`, that belong to the same test
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suite `FactorialTest`.
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When naming your test suites and tests, you should follow the same convention as
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for
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[naming functions and classes](https://google.github.io/styleguide/cppguide.html#Function_Names).
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**Availability**: Linux, Windows, Mac.
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## Test Fixtures: Using the Same Data Configuration for Multiple Tests {#same-data-multiple-tests}
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If you find yourself writing two or more tests that operate on similar data, you
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can use a *test fixture*. This allows you to reuse the same configuration of
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objects for several different tests.
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To create a fixture:
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1. Derive a class from `::testing::Test` . Start its body with `protected:`, as
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we'll want to access fixture members from sub-classes.
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2. Inside the class, declare any objects you plan to use.
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3. If necessary, write a default constructor or `SetUp()` function to prepare
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the objects for each test. A common mistake is to spell `SetUp()` as
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**`Setup()`** with a small `u` - Use `override` in C++11 to make sure you
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spelled it correctly.
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4. If necessary, write a destructor or `TearDown()` function to release any
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resources you allocated in `SetUp()` . To learn when you should use the
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constructor/destructor and when you should use `SetUp()/TearDown()`, read
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the [FAQ](faq.md#CtorVsSetUp).
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5. If needed, define subroutines for your tests to share.
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When using a fixture, use `TEST_F()` instead of `TEST()` as it allows you to
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access objects and subroutines in the test fixture:
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```c++
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TEST_F(TestFixtureName, TestName) {
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... test body ...
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}
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```
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Like `TEST()`, the first argument is the test suite name, but for `TEST_F()`
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this must be the name of the test fixture class. You've probably guessed: `_F`
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is for fixture.
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Unfortunately, the C++ macro system does not allow us to create a single macro
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that can handle both types of tests. Using the wrong macro causes a compiler
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error.
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Also, you must first define a test fixture class before using it in a
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`TEST_F()`, or you'll get the compiler error "`virtual outside class
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declaration`".
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For each test defined with `TEST_F()`, googletest will create a *fresh* test
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fixture at runtime, immediately initialize it via `SetUp()`, run the test,
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clean up by calling `TearDown()`, and then delete the test fixture. Note that
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different tests in the same test suite have different test fixture objects, and
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googletest always deletes a test fixture before it creates the next one.
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googletest does **not** reuse the same test fixture for multiple tests. Any
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changes one test makes to the fixture do not affect other tests.
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As an example, let's write tests for a FIFO queue class named `Queue`, which has
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the following interface:
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```c++
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template <typename E> // E is the element type.
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class Queue {
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public:
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Queue();
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void Enqueue(const E& element);
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E* Dequeue(); // Returns NULL if the queue is empty.
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size_t size() const;
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...
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};
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```
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First, define a fixture class. By convention, you should give it the name
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`FooTest` where `Foo` is the class being tested.
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```c++
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class QueueTest : public ::testing::Test {
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protected:
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void SetUp() override {
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q1_.Enqueue(1);
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q2_.Enqueue(2);
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q2_.Enqueue(3);
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}
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// void TearDown() override {}
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Queue<int> q0_;
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Queue<int> q1_;
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Queue<int> q2_;
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};
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```
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In this case, `TearDown()` is not needed since we don't have to clean up after
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each test, other than what's already done by the destructor.
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Now we'll write tests using `TEST_F()` and this fixture.
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```c++
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TEST_F(QueueTest, IsEmptyInitially) {
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EXPECT_EQ(q0_.size(), 0);
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}
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TEST_F(QueueTest, DequeueWorks) {
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int* n = q0_.Dequeue();
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EXPECT_EQ(n, nullptr);
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n = q1_.Dequeue();
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ASSERT_NE(n, nullptr);
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EXPECT_EQ(*n, 1);
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EXPECT_EQ(q1_.size(), 0);
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delete n;
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n = q2_.Dequeue();
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ASSERT_NE(n, nullptr);
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EXPECT_EQ(*n, 2);
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EXPECT_EQ(q2_.size(), 1);
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delete n;
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}
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```
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The above uses both `ASSERT_*` and `EXPECT_*` assertions. The rule of thumb is
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to use `EXPECT_*` when you want the test to continue to reveal more errors after
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the assertion failure, and use `ASSERT_*` when continuing after failure doesn't
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make sense. For example, the second assertion in the `Dequeue` test is
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`ASSERT_NE(nullptr, n)`, as we need to dereference the pointer `n` later, which
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would lead to a segfault when `n` is `NULL`.
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When these tests run, the following happens:
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1. googletest constructs a `QueueTest` object (let's call it `t1`).
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2. `t1.SetUp()` initializes `t1`.
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3. The first test (`IsEmptyInitially`) runs on `t1`.
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4. `t1.TearDown()` cleans up after the test finishes.
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5. `t1` is destructed.
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6. The above steps are repeated on another `QueueTest` object, this time
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running the `DequeueWorks` test.
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**Availability**: Linux, Windows, Mac.
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## Invoking the Tests
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`TEST()` and `TEST_F()` implicitly register their tests with googletest. So,
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unlike with many other C++ testing frameworks, you don't have to re-list all
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your defined tests in order to run them.
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After defining your tests, you can run them with `RUN_ALL_TESTS()`, which
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returns `0` if all the tests are successful, or `1` otherwise. Note that
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`RUN_ALL_TESTS()` runs *all tests* in your link unit--they can be from
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different test suites, or even different source files.
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When invoked, the `RUN_ALL_TESTS()` macro:
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* Saves the state of all googletest flags.
|
|
|
|
* Creates a test fixture object for the first test.
|
|
|
|
* Initializes it via `SetUp()`.
|
|
|
|
* Runs the test on the fixture object.
|
|
|
|
* Cleans up the fixture via `TearDown()`.
|
|
|
|
* Deletes the fixture.
|
|
|
|
* Restores the state of all googletest flags.
|
|
|
|
* Repeats the above steps for the next test, until all tests have run.
|
|
|
|
If a fatal failure happens the subsequent steps will be skipped.
|
|
|
|
{: .callout .important}
|
|
> IMPORTANT: You must **not** ignore the return value of `RUN_ALL_TESTS()`, or
|
|
> you will get a compiler error. The rationale for this design is that the
|
|
> automated testing service determines whether a test has passed based on its
|
|
> exit code, not on its stdout/stderr output; thus your `main()` function must
|
|
> return the value of `RUN_ALL_TESTS()`.
|
|
>
|
|
> Also, you should call `RUN_ALL_TESTS()` only **once**. Calling it more than
|
|
> once conflicts with some advanced googletest features (e.g., thread-safe
|
|
> [death tests](advanced.md#death-tests)) and thus is not supported.
|
|
|
|
**Availability**: Linux, Windows, Mac.
|
|
|
|
## Writing the main() Function
|
|
|
|
Most users should _not_ need to write their own `main` function and instead link
|
|
with `gtest_main` (as opposed to with `gtest`), which defines a suitable entry
|
|
point. See the end of this section for details. The remainder of this section
|
|
should only apply when you need to do something custom before the tests run that
|
|
cannot be expressed within the framework of fixtures and test suites.
|
|
|
|
If you write your own `main` function, it should return the value of
|
|
`RUN_ALL_TESTS()`.
|
|
|
|
You can start from this boilerplate:
|
|
|
|
```c++
|
|
#include "this/package/foo.h"
|
|
|
|
#include "gtest/gtest.h"
|
|
|
|
namespace my {
|
|
namespace project {
|
|
namespace {
|
|
|
|
// The fixture for testing class Foo.
|
|
class FooTest : public ::testing::Test {
|
|
protected:
|
|
// You can remove any or all of the following functions if their bodies would
|
|
// be empty.
|
|
|
|
FooTest() {
|
|
// You can do set-up work for each test here.
|
|
}
|
|
|
|
~FooTest() override {
|
|
// You can do clean-up work that doesn't throw exceptions here.
|
|
}
|
|
|
|
// If the constructor and destructor are not enough for setting up
|
|
// and cleaning up each test, you can define the following methods:
|
|
|
|
void SetUp() override {
|
|
// Code here will be called immediately after the constructor (right
|
|
// before each test).
|
|
}
|
|
|
|
void TearDown() override {
|
|
// Code here will be called immediately after each test (right
|
|
// before the destructor).
|
|
}
|
|
|
|
// Class members declared here can be used by all tests in the test suite
|
|
// for Foo.
|
|
};
|
|
|
|
// Tests that the Foo::Bar() method does Abc.
|
|
TEST_F(FooTest, MethodBarDoesAbc) {
|
|
const std::string input_filepath = "this/package/testdata/myinputfile.dat";
|
|
const std::string output_filepath = "this/package/testdata/myoutputfile.dat";
|
|
Foo f;
|
|
EXPECT_EQ(f.Bar(input_filepath, output_filepath), 0);
|
|
}
|
|
|
|
// Tests that Foo does Xyz.
|
|
TEST_F(FooTest, DoesXyz) {
|
|
// Exercises the Xyz feature of Foo.
|
|
}
|
|
|
|
} // namespace
|
|
} // namespace project
|
|
} // namespace my
|
|
|
|
int main(int argc, char **argv) {
|
|
::testing::InitGoogleTest(&argc, argv);
|
|
return RUN_ALL_TESTS();
|
|
}
|
|
```
|
|
|
|
The `::testing::InitGoogleTest()` function parses the command line for
|
|
googletest flags, and removes all recognized flags. This allows the user to
|
|
control a test program's behavior via various flags, which we'll cover in
|
|
the [AdvancedGuide](advanced.md). You **must** call this function before calling
|
|
`RUN_ALL_TESTS()`, or the flags won't be properly initialized.
|
|
|
|
On Windows, `InitGoogleTest()` also works with wide strings, so it can be used
|
|
in programs compiled in `UNICODE` mode as well.
|
|
|
|
But maybe you think that writing all those `main` functions is too much work? We
|
|
agree with you completely, and that's why Google Test provides a basic
|
|
implementation of main(). If it fits your needs, then just link your test with
|
|
the `gtest_main` library and you are good to go.
|
|
|
|
{: .callout .note}
|
|
NOTE: `ParseGUnitFlags()` is deprecated in favor of `InitGoogleTest()`.
|
|
|
|
## Known Limitations
|
|
|
|
* Google Test is designed to be thread-safe. The implementation is thread-safe
|
|
on systems where the `pthreads` library is available. It is currently
|
|
_unsafe_ to use Google Test assertions from two threads concurrently on
|
|
other systems (e.g. Windows). In most tests this is not an issue as usually
|
|
the assertions are done in the main thread. If you want to help, you can
|
|
volunteer to implement the necessary synchronization primitives in
|
|
`gtest-port.h` for your platform.
|