audk/UnitTestFrameworkPkg
Gua Guo 3701f105fa UnitTestFrameworkPkg: Add code coverage support for GCC
In order to collect code coverage after running executable
file, generate *.gcda and *.gcno file that require by lcov tool
to generate code coverage report.

Reviewed-by: Michael D Kinney <michael.d.kinney@intel.com>
Cc: Sean Brogan <sean.brogan@microsoft.com>
Cc: Bret Barkelew <Bret.Barkelew@microsoft.com>
Reviewed-by: Michael Kubacki <mikuback@linux.microsoft.com>
Signed-off-by: Gua Guo <gua.guo@intel.com>
2023-01-04 02:06:01 +00:00
..
Include/Library UnitTestFrameworkPkg: Modify APIs in UnitTestPersistenceLib 2022-12-14 13:34:33 +00:00
Library UnitTestFrameworkPkg/UnitTestLib: Print expected Status on ASSERT fail 2022-12-14 23:48:30 +00:00
PrivateInclude UnitTestFrameworkPkg: Library classes private to public 2022-12-01 21:01:21 +00:00
Test UnitTestFrameworkPkg: Add googletest submodule and GoogleTestLib 2022-11-11 05:46:51 +00:00
ReadMe.md UnitTestFrameworkPkg: Add code coverage support for GCC 2023-01-04 02:06:01 +00:00
UnitTestFrameworkPkg.ci.yaml UnitTestFrameworkPkg: Add code coverage support for GCC 2023-01-04 02:06:01 +00:00
UnitTestFrameworkPkg.dec UnitTestFrameworkPkg: Library classes private to public 2022-12-01 21:01:21 +00:00
UnitTestFrameworkPkg.dsc UnitTestFrameworkPkg: Add UnitTestUefiBootServicesTableLib 2022-11-07 16:07:33 +00:00
UnitTestFrameworkPkg.uni
UnitTestFrameworkPkgHost.dsc.inc UnitTestFrameworkPkg: Add code coverage support for GCC 2023-01-04 02:06:01 +00:00
UnitTestFrameworkPkgTarget.dsc.inc UnitTestFrameworkPkg/UnitTestLib: Add checks for ASSERT() 2020-07-15 05:25:21 +00:00

ReadMe.md

Unit Test Framework Package

About

This package provides unit test frameworks capable of building tests for multiple contexts including the UEFI shell environment and host-based environments. It allows for unit test development to focus on the tests and leave error logging, result formatting, context persistence, and test running to the framework. The unit test framework works well for low level unit tests as well as system level tests and fits easily in automation frameworks.

Framework

The first unit test framework is called Framework and is implemented as a set of EDK II libraries. The Framework supports both host-based unit tests and target-based unit tests that share the same source style, macros, and APIs. In some scenarios, the same unit test case sources can be built for both host-based unit test execution and target-based unit test execution. Host-based unit tests that require mocked interfaces can use the mocking infrastructure provided by cmocka that is included in the UnitTestFrameworkPkg as a submodule.

GoogleTest

The second unit test framework supported by the UnitTestFrameworkPkg is GoogleTest that can be used to implement host-based unit tests. Use of GoogleTest for target-based unit tests of EDK II components is not supported. If a host-based unit test requires mocked interfaces, then the Framework with cmocka support should be used instead. Enabling support for mocked interfaces with GoogleTest is being actively investigated. GoogleTest on GitHub is included in the UnitTestFrameworkPkg as a submodule.

GoogleTest requires less overhead to register test suites and test cases compared to the Framework. There are also a number of tools that layer on top of GoogleTest that improve developer productivity. One example is the VS Code extension C++ TestMate that may be used to implement, run, and debug unit tests implemented using GoogleTest.

If a component can be tested with host-based unit tests without support for mocked interfaces, then GoogleTest is recommended. The MdePkg contains a port of the BaseSafeIntLib unit tests in the GoogleTest style so the differences between GoogleTest and Framework unit tests can be reviewed. The paths to the BaseSafeIntLib unit tests are:

  • MdePkg\Test\UnitTest\Library\BaseSafeIntLib
  • MdePkg\Test\GoogleTest\Library\BaseSafeIntLib

Framework and GoogleTest Feature Comparison

Feature Framework GoogleTest
Host Based Unit Tests YES YES
Target Based Unit Tests YES NO
Unit Test Source Language C C++
Register Test Suite YES Auto
Register Test Case YES Auto
Death/Expected Assert Tests YES YES
Setup/Teardown Hooks YES YES
Value-Parameterized Tests NO YES
Typed Tests NO YES
Type-Parameterized Tests NO YES
Timeout Support NO YES
Mocking Support Cmocka NO
JUNIT XML Reports YES YES
Execute subset of tests NO YES
VS Code Extensions NO YES

Framework Libraries

UnitTestLib

The main "framework" library. The core of the framework is the Framework object, which can have any number of test cases and test suites registered with it. The Framework object is also what drives test execution.

The Framework also provides helper macros and functions for checking test conditions and reporting errors. Status and error info will be logged into the test context. There are a number of Assert macros that make the unit test code friendly to view and easy to understand.

Finally, the Framework also supports logging strings during the test execution. This data is logged to the test context and will be available in the test reporting phase. This should be used for logging test details and helpful messages to resolve test failures.

UnitTestPersistenceLib

Persistence lib has the main job of saving and restoring test context to a storage medium so that for tests that require exiting the active process and then resuming state can be maintained. This is critical in supporting a system reboot in the middle of a test run.

UnitTestResultReportLib

Library provides function to run at the end of a framework test run and handles formatting the report. This is a common customization point and allows the unit test framework to fit its output reports into other test infrastructure. In this package simple library instances have been supplied to output test results to the console as plain text.

Framework Samples

There is a sample unit test provided as both an example of how to write a unit test and leverage many of the features of the framework. This sample can be found in the Test/UnitTest/Sample/SampleUnitTest directory.

The sample is provided in PEI, SMM, DXE, and UEFI App flavors. It also has a flavor for the HOST_APPLICATION build type, which can be run on a host system without needing a target.

Framework Usage

This section is built a lot like a "Getting Started". We'll go through some of the components that are needed when constructing a unit test and some of the decisions that are made by the test writer. We'll also describe how to check for expected conditions in test cases and a bit of the logging characteristics.

Most of these examples will refer to the SampleUnitTestUefiShell app found in this package.

Framework Requirements - INF

In our INF file, we'll need to bring in the UnitTestLib library. Conveniently, the interface header for the UnitTestLib is located in MdePkg, so you shouldn't need to depend on any other packages. As long as your DSC file knows where to find the lib implementation that you want to use, you should be good to go.

See this example in 'SampleUnitTestUefiShell.inf'...

[Packages]
  MdePkg/MdePkg.dec

[LibraryClasses]
  UefiApplicationEntryPoint
  BaseLib
  DebugLib
  UnitTestLib
  PrintLib

Also, if you want you test to automatically be picked up by the Test Runner plugin, you will need to make sure that the module BASE_NAME contains the word Test...

[Defines]
  BASE_NAME      = SampleUnitTestUefiShell

Framework Requirements - Code

Not to state the obvious, but let's make sure we have the following include before getting too far along...

#include <Library/UnitTestLib.h>

Now that we've got that squared away, let's look at our 'Main()'' routine (or DriverEntryPoint() or whatever).

Framework Configuration

Everything in the UnitTestFrameworkPkg framework is built around an object called -- conveniently -- the Framework. This Framework object will contain all the information about our test, the test suites and test cases associated with it, the current location within the test pass, and any results that have been recorded so far.

To get started with a test, we must first create a Framework instance. The function for this is InitUnitTestFramework. It takes in CHAR8 strings for the long name, short name, and test version. The long name and version strings are just for user presentation and relatively flexible. The short name will be used to name any cache files and/or test results, so should be a name that makes sense in that context. These strings are copied internally to the Framework, so using stack-allocated or literal strings is fine.

In the 'SampleUnitTestUefiShell' app, the module name is used as the short name, so the initialization looks like this.

DEBUG(( DEBUG_INFO, "%a v%a\n", UNIT_TEST_APP_NAME, UNIT_TEST_APP_VERSION ));

//
// Start setting up the test framework for running the tests.
//
Status = InitUnitTestFramework( &Framework, UNIT_TEST_APP_NAME, gEfiCallerBaseName, UNIT_TEST_APP_VERSION );

The &Framework returned here is the handle to the Framework. If it's successfully returned, we can start adding test suites and test cases.

Test suites exist purely to help organize test cases and to differentiate the results in reports. If you're writing a small unit test, you can conceivably put all test cases into a single suite. However, if you end up with 20+ test cases, it may be beneficial to organize them according to purpose. You must have at least one test suite, even if it's just a catch-all. The function to create a test suite is CreateUnitTestSuite. It takes in a handle to the Framework object, a CHAR8 string for the suite title and package name, and optional function pointers for a setup function and a teardown function.

The suite title is for user presentation. The package name is for xUnit type reporting and uses a '.'-separated hierarchical format (see 'SampleUnitTestApp' for example). If provided, the setup and teardown functions will be called once at the start of the suite (before any tests have run) and once at the end of the suite (after all tests have run), respectively. If either or both of these are unneeded, pass NULL. The function prototypes are UNIT_TEST_SUITE_SETUP and UNIT_TEST_SUITE_TEARDOWN.

Looking at 'SampleUnitTestUefiShell' app, you can see that the first test suite is created as below...

//
// Populate the SimpleMathTests Unit Test Suite.
//
Status = CreateUnitTestSuite( &SimpleMathTests, Fw, "Simple Math Tests", "Sample.Math", NULL, NULL );

This test suite has no setup or teardown functions. The &SimpleMathTests returned here is a handle to the suite and will be used when adding test cases.

Great! Now we've finished some of the cruft, red tape, and busy work. We're ready to add some tests. Adding a test to a test suite is accomplished with the -- you guessed it -- AddTestCase function. It takes in the suite handle; a CHAR8 string for the description and class name; a function pointer for the test case itself; additional, optional function pointers for prerequisite check and cleanup routines; and an optional pointer to a context structure.

Okay, that's a lot. Let's take it one piece at a time. The description and class name strings are very similar in usage to the suite title and package name strings in the test suites. The former is for user presentation and the latter is for xUnit parsing. The test case function pointer is what is executed as the "test" and the prototype should be UNIT_TEST_FUNCTION. The last three parameters require a little bit more explaining.

The prerequisite check function has a prototype of UNIT_TEST_PREREQUISITE and -- if provided -- will be called immediately before the test case. If this function returns any error, the test case will not be run and will be recorded as UNIT_TEST_ERROR_PREREQUISITE_NOT_MET. The cleanup function (prototype UNIT_TEST_CLEANUP) will be called immediately after the test case to provide an opportunity to reset any global state that may have been changed in the test case. In the event of a prerequisite failure, the cleanup function will also be skipped. If either of these functions is not needed, pass NULL.

The context pointer is entirely case-specific. It will be passed to the test case upon execution. One of the purposes of the context pointer is to allow test case reuse with different input data. (Another use is for testing that wraps around a system reboot, but that's beyond the scope of this guide.) The test case must know how to interpret the context pointer, so it could be a simple value, or it could be a complex structure. If unneeded, pass NULL.

In 'SampleUnitTestUefiShell' app, the first test case is added using the code below...

AddTestCase( SimpleMathTests, "Adding 1 to 1 should produce 2", "Addition", OnePlusOneShouldEqualTwo, NULL, NULL, NULL );

This test case calls the function OnePlusOneShouldEqualTwo and has no prerequisite, cleanup, or context.

Once all the suites and cases are added, it's time to run the Framework.

//
// Execute the tests.
//
Status = RunAllTestSuites( Framework );

Framework - A Simple Test Case

We'll take a look at the below test case from 'SampleUnitTestApp'...

UNIT_TEST_STATUS
EFIAPI
OnePlusOneShouldEqualTwo (
  IN UNIT_TEST_FRAMEWORK_HANDLE  Framework,
  IN UNIT_TEST_CONTEXT           Context
  )
{
  UINTN     A, B, C;

  A = 1;
  B = 1;
  C = A + B;

  UT_ASSERT_EQUAL(C, 2);
  return UNIT_TEST_PASSED;
} // OnePlusOneShouldEqualTwo()

The prototype for this function matches the UNIT_TEST_FUNCTION prototype. It takes in a handle to the Framework itself and the context pointer. The context pointer could be cast and interpreted as anything within this test case, which is why it's important to configure contexts carefully. The test case returns a value of UNIT_TEST_STATUS, which will be recorded in the Framework and reported at the end of all suites.

In this test case, the UT_ASSERT_EQUAL assertion is being used to establish that the business logic has functioned correctly. There are several assertion macros, and you are encouraged to use one that matches as closely to your intended test criterium as possible, because the logging is specific to the macro and more specific macros have more detailed logs. When in doubt, there are always UT_ASSERT_TRUE and UT_ASSERT_FALSE. Assertion macros that fail their test criterium will immediately return from the test case with UNIT_TEST_ERROR_TEST_FAILED and log an error string. Note that this early return can have implications for memory leakage.

At the end, if all test criteria pass, you should return UNIT_TEST_PASSED.

Framework - More Complex Cases

To write more advanced tests, first look at all the Assertion and Logging macros provided in the framework.

Beyond that, if you're writing host-based tests and want to take a dependency on the UnitTestFrameworkPkg, you can leverage the cmocka.h interface and write tests with all the features of the Cmocka framework.

Documentation for Cmocka can be found here: https://api.cmocka.org/

GoogleTest Samples

There is a sample unit test provided as both an example of how to write a unit test and leverage many of the GoogleTest features. This sample can be found in the Test/GoogleTest/Sample/SampleGoogleTest directory.

The sample is provided for the HOST_APPLICATION build type, which can be run on a host system without needing a target.

GoogleTest Usage

This section is built a lot like a "Getting Started". We'll go through some of the components that are needed when constructing a unit test and some of the decisions that are made by the test writer. We'll also describe how to check for expected conditions in test cases and a bit of the logging characteristics.

Most of these examples will refer to the SampleGoogleTestHost app found in this package.

GoogleTest Requirements - INF

In our INF file, we'll need to bring in the GoogleTest library. Conveniently, the interface header for the GoogleTest is in UnitTestFrameworkPkg, so you shouldn't need to depend on any other packages. As long as your DSC file knows where to find the lib implementation that you want to use, you should be good to go.

See this example in 'SampleGoogleTestHost.inf'...

[Packages]
  MdePkg/MdePkg.dec
  UnitTestFrameworkPkg/UnitTestFrameworkPkg.dec

[LibraryClasses]
  GoogleTestLib
  BaseLib
  DebugLib

Also, if you want you test to automatically be picked up by the Test Runner plugin, you will need to make sure that the module BASE_NAME contains the word Test...

[Defines]
  BASE_NAME      = SampleGoogleTestHost

GoogleTest Requirements - Code

Not to state the obvious, but let's make sure we have the following include before getting too far along...

#include <gtest/gtest.h>
extern "C" {
  #include <Uefi.h>
  #include <Library/BaseLib.h>
  #include <Library/DebugLib.h>
}

GoogleTest applications are implemented in C++. The first include brings in the GoogleTest definitions. Other EDK II related include files must be wrapped in extern "C" {} because they are C include files. Link failures will occur if this is not done.

Now that we've got that squared away, let's look at our 'Main()'' routine (or DriverEntryPoint() or whatever).

GoogleTest Configuration

Unlike the Framework, GoogleTest does not require test suites or test cases to be registered. Instead, the test cases declare the test suite name and test case name as part of their implementation. The only requirement for GoogleTest is to have a main() function that initialize the GoogleTest infrastructure and call the service RUN_ALL_TESTS() to run all the unit tests.

int main(int argc, char* argv[]) {
  testing::InitGoogleTest(&argc, argv);
  return RUN_ALL_TESTS();
}

GoogleTest - A Simple Test Case

We'll look at the below test case from 'SampleGoogleTestHost'...

TEST(SimpleMathTests, OnePlusOneShouldEqualTwo) {
  UINTN  A;
  UINTN  B;
  UINTN  C;

  A = 1;
  B = 1;
  C = A + B;

  ASSERT_EQ (C, 2);
}

This uses the simplest form of a GoogleTest unit test using TEST() that declares the test suite name and the unit test name within that test suite. The unit test performs actions and typically makes calls to the code under test and contains test assertions to verify that the code under test behaves as expected for the given inputs.

In this test case, the ASSERT_EQ assertion is being used to establish that the business logic has functioned correctly. There are several assertion macros, and you are encouraged to use one that matches as closely to your intended test criterium as possible, because the logging is specific to the macro and more specific macros have more detailed logs. When in doubt, there are always ASSERT_TRUE and ASSERT_FALSE. Assertion macros that fail their test criterium will immediately return from the test case with a failed status and log an error string. Note that this early return can have implications for memory leakage.

There is no return status from a GooglTest unit test. If no assertions are triggered then the unit test has a passing status.

GoogleTest - More Complex Cases

To write more advanced tests, take a look at the GoogleTest User's Guide.

Development

Iterating on a Single Test

When using the EDK2 Pytools for CI testing, the host-based unit tests will be built and run on any build that includes the NOOPT build target.

If you are trying to iterate on a single test, a convenient pattern is to build only that test module. For example, the following command will build only the SafeIntLib host-based test from the MdePkg...

stuart_ci_build -c .pytool/CISettings.py TOOL_CHAIN_TAG=VS2017 -p MdePkg -t NOOPT BUILDMODULE=MdePkg/Test/UnitTest/Library/BaseSafeIntLib/TestBaseSafeIntLib.inf

Hooking BaseLib

Most unit test mocking can be performed by the functions provided in the UnitTestFrameworkPkg libraries, but since BaseLib is consumed by the Framework itself, it requires different techniques to substitute parts of the functionality.

To solve some of this, the UnitTestFrameworkPkg consumes a special implementation of BaseLib for host-based tests. This implementation contains a hook table that can be used to substitute test functionality for any of the BaseLib functions. By default, this implementation will use the underlying BaseLib implementation, so the unit test writer only has to supply minimal code to test a particular case.

Debugging the Framework Itself

While most of the tests that are produced by the UnitTestFrameworkPkg are easy to step through in a debugger, the Framework itself consumes code (mostly Cmocka) that sets its own build flags. These flags cause parts of the Framework to not export symbols and captures exceptions, and as such are harder to debug. We have provided a Stuart parameter to force symbolic debugging to be enabled.

You can run a build by adding the BLD_*_UNIT_TESTING_DEBUG=TRUE parameter to enable this build option.

stuart_ci_build -c .pytool/CISettings.py TOOL_CHAIN_TAG=VS2019 -p MdePkg -t NOOPT BLD_*_UNIT_TESTING_DEBUG=TRUE

Building and Running Host-Based Tests

The EDK2 CI infrastructure provides a convenient way to run all host-based tests -- in the the entire tree or just selected packages -- and aggregate all the reports, including highlighting any failures. This functionality is provided through the Stuart build system (published by EDK2-PyTools) and the NOOPT build target. The sections that follow use Framework examples. Unit tests based on GoogleTest are built and run the same way. The text output and JUNIT XML output format have small differences.

Building Locally

First, to make sure you're working with the latest PyTools, run the following command:

# Would recommend running this in a Python venv, but that's out of scope for this doc.
python -m pip install --upgrade -r ./pip-requirements.txt

After that, the following commands will set up the build and run the host-based tests.

# Setup repo for building
# stuart_setup -c ./.pytool/CISettings.py TOOL_CHAIN_TAG=<GCC5, VS2019, etc.>
stuart_setup -c ./.pytool/CISettings.py TOOL_CHAIN_TAG=VS2019

# Update all binary dependencies
# stuart_update -c ./.pytool/CISettings.py TOOL_CHAIN_TAG=<GCC5, VS2019, etc.>
stuart_update -c ./.pytool/CISettings.py TOOL_CHAIN_TAG=VS2019

# Build and run the tests
# stuart_ci_build -c ./.pytool/CISettings.py TOOL_CHAIN_TAG=<GCC5, VS2019, etc.> -t NOOPT [-p <Package Name>]
stuart_ci_build -c ./.pytool/CISettings.py TOOL_CHAIN_TAG=VS2019 -t NOOPT -p MdePkg

Evaluating the Results

In your immediate output, any build failures will be highlighted. You can see these below as "WARNING" and "ERROR" messages.

(edk_env) PS C:\_uefi\edk2> stuart_ci_build -c .\.pytool\CISettings.py TOOL_CHAIN_TAG=VS2019 -t NOOPT -p MdePkg

SECTION - Init SDE
SECTION - Loading Plugins
SECTION - Start Invocable Tool
SECTION - Getting Environment
SECTION - Loading plugins
SECTION - Building MdePkg Package
PROGRESS - --Running MdePkg: Host Unit Test Compiler Plugin NOOPT --
WARNING - Allowing Override for key TARGET_ARCH
PROGRESS - Start time: 2020-07-27 17:18:08.521672
PROGRESS - Setting up the Environment
PROGRESS - Running Pre Build
PROGRESS - Running Build NOOPT
PROGRESS - Running Post Build
SECTION - Run Host based Unit Tests
SUBSECTION - Testing for architecture: X64
WARNING - TestBaseSafeIntLibHost.exe Test Failed
WARNING -   Test SafeInt8ToUint8 - UT_ASSERT_EQUAL(0x5b:5b, Result:5c)
c:\_uefi\edk2\MdePkg\Test\UnitTest\Library\BaseSafeIntLib\TestBaseSafeIntLib.c:35: error: Failure!
ERROR - Plugin Failed: Host-Based Unit Test Runner returned 1
CRITICAL - Post Build failed
PROGRESS - End time: 2020-07-27 17:18:19.792313  Total time Elapsed: 0:00:11
ERROR - --->Test Failed: Host Unit Test Compiler Plugin NOOPT returned 1
ERROR - Overall Build Status: Error
PROGRESS - There were 1 failures out of 1 attempts
SECTION - Summary
ERROR - Error

(edk_env) PS C:\_uefi\edk2>

If a test fails, you can run it manually to get more details...

(edk_env) PS C:\_uefi\edk2> .\Build\MdePkg\HostTest\NOOPT_VS2019\X64\TestBaseSafeIntLibHost.exe

Int Safe Lib Unit Test Application v0.1
---------------------------------------------------------
------------     RUNNING ALL TEST SUITES   --------------
---------------------------------------------------------
---------------------------------------------------------
RUNNING TEST SUITE: Int Safe Conversions Test Suite
---------------------------------------------------------
[==========] Running 71 test(s).
[ RUN      ] Test SafeInt8ToUint8
[  ERROR   ] --- UT_ASSERT_EQUAL(0x5b:5b, Result:5c)
[   LINE   ] --- c:\_uefi\edk2\MdePkg\Test\UnitTest\Library\BaseSafeIntLib\TestBaseSafeIntLib.c:35: error: Failure!
[  FAILED  ] Test SafeInt8ToUint8
[ RUN      ] Test SafeInt8ToUint16
[       OK ] Test SafeInt8ToUint16
[ RUN      ] Test SafeInt8ToUint32
[       OK ] Test SafeInt8ToUint32
[ RUN      ] Test SafeInt8ToUintn
[       OK ] Test SafeInt8ToUintn
...

You can also, if you are so inclined, read the output from the exact instance of the test that was run during stuart_ci_build. The output file can be found on a path that looks like:

Build/<Package>/HostTest/<Arch>/<TestName>.<TestSuiteName>.<Arch>.result.xml

A sample of this output looks like:

<!--
  Excerpt taken from:
  Build\MdePkg\HostTest\NOOPT_VS2019\X64\TestBaseSafeIntLibHost.exe.Int Safe Conversions Test Suite.X64.result.xml
  -->
<?xml version="1.0" encoding="UTF-8" ?>
<testsuites>
  <testsuite name="Int Safe Conversions Test Suite" time="0.000" tests="71" failures="1" errors="0" skipped="0" >
    <testcase name="Test SafeInt8ToUint8" time="0.000" >
      <failure><![CDATA[UT_ASSERT_EQUAL(0x5c:5c, Result:5b)
c:\_uefi\MdePkg\Test\UnitTest\Library\BaseSafeIntLib\TestBaseSafeIntLib.c:35: error: Failure!]]></failure>
    </testcase>
    <testcase name="Test SafeInt8ToUint16" time="0.000" >
    </testcase>
    <testcase name="Test SafeInt8ToUint32" time="0.000" >
    </testcase>
    <testcase name="Test SafeInt8ToUintn" time="0.000" >
    </testcase>

XML Reporting Mode

Unit test applications using Framework are built using Cmocka that requires the following environment variables to be set to generate structured XML output rather than text:

CMOCKA_MESSAGE_OUTPUT=xml
CMOCKA_XML_FILE=<absolute or relative path to output file>

Unit test applications using GoogleTest require the following environment variable to be set to generate structured XML output rather than text:

GTEST_OUTPUT=xml:<absolute or relative path to output file>

This mode is used by the test running plugin to aggregate the results for CI test status reporting in the web view.

Code Coverage

Host based Unit Tests will automatically enable coverage data.

For Windows, This is primarily leverage for pipeline builds, but this can be leveraged locally using the OpenCppCoverage windows tool to parse coverage data to cobertura xml format.

  • Windows Prerequisite

    Download and install https://github.com/OpenCppCoverage/OpenCppCoverage/releases
    python -m pip install --upgrade -r ./pip-requirements.txt
    stuart_ci_build -c .pytool/CISettings.py  -t NOOPT TOOL_CHAIN_TAG=VS2019 -p MdeModulePkg
    Open Build/coverage.xml
    
    • How to see code coverage data on IDE Visual Studio
      Open Visual Studio VS2019 or above version
      Click "Tools" -> "OpenCppCoverage Settings"
      Fill your execute file into "Program to run:"
      Click "Tools" -> "Run OpenCppCoverage"
      

For Linux, This is primarily leveraged for pipeline builds, but this can be leveraged locally using the lcov linux tool, and parsed using the lcov_cobertura python tool to parse it to cobertura xml format.

  • Linux Prerequisite
    sudo apt-get install -y lcov
    python -m pip install --upgrade -r ./pip-requirements.txt
    stuart_ci_build -c .pytool/CISettings.py  -t NOOPT TOOL_CHAIN_TAG=GCC5 -p MdeModulePkg
    Open Build/coverage.xml
    
    • How to see code coverage data on IDE Visual Studio Code
      Download plugin "Coverage Gutters"
      Press Hot Key "Ctrl + Shift + P" and click option "Coverage Gutters: Display Coverage"
      

Important Note

This works on both Windows and Linux but is currently limited to x64 architectures. Working on getting others, but we also welcome contributions.

Framework Known Limitations

PEI, DXE, SMM

While sample tests have been provided for these execution environments, only cursory build validation has been performed. Care has been taken while designing the frameworks to allow for execution during boot phases, but only UEFI Shell and host-based tests have been thoroughly evaluated. Full support for PEI, DXE, and SMM is forthcoming, but should be considered beta/staging for now.

Host-Based Support vs Other Tests

The host-based test framework is powered internally by the Cmocka framework. As such, it has abilities that the target-based tests don't (yet). It would be awesome if this meant that it was a super set of the target-based tests, and it worked just like the target-based tests but with more features. Unfortunately, this is not the case. While care has been taken to keep them as close as possible, there are a few known inconsistencies that we're still ironing out. For example, the logging messages in the target-based tests are cached internally and associated with the running test case. They can be saved later as part of the reporting lib. This isn't currently possible with host-based. Only the assertion failures are logged.

We will continue trying to make these as similar as possible.

Unit Test Location/Layout Rules

Code/Test Location
Host-Based Unit Tests for a Library/Protocol/PPI/GUID Interface If what's being tested is an interface (e.g. a library with a public header file, like DebugLib), the test should be scoped to the parent package.
Example: MdePkg/Test/UnitTest/[Library/Protocol/Ppi/Guid]/

A real-world example of this is the BaseSafeIntLib test in MdePkg.
MdePkg/Test/UnitTest/Library/BaseSafeIntLib/TestBaseSafeIntLibHost.inf
Host-Based Unit Tests for a Library/Driver (PEI/DXE/SMM) implementation If what's being tested is a specific implementation (e.g. BaseDebugLibSerialPort for DebugLib), the test should be scoped to the implementation directory itself, in a UnitTest subdirectory.

Module Example: MdeModulePkg/Universal/EsrtFmpDxe/UnitTest/
Library Example: MdePkg/Library/BaseMemoryLib/UnitTest/
Host-Based Tests for a Functionality or Feature If you're writing a functional test that operates at the module level (i.e. if it's more than a single file or library), the test should be located in the package-level Tests directory under the HostFuncTest subdirectory.
For example, if you were writing a test for the entire FMP Device Framework, you might put your test in:
FmpDevicePkg/Test/HostFuncTest/FmpDeviceFramework

If the feature spans multiple packages, it's location should be determined by the package owners related to the feature.
Non-Host-Based (PEI/DXE/SMM/Shell) Tests for a Functionality or Feature Similar to Host-Based, if the feature is in one package, should be located in the *Pkg/Test/[Shell/Dxe/Smm/Pei]Test directory.

If the feature spans multiple packages, it's location should be determined by the package owners related to the feature.

USAGE EXAMPLES
PEI Example: MP_SERVICE_PPI. Or check MTRR configuration in a notification function.
SMM Example: a test in a protocol callback function. (It is different with the solution that SmmAgent+ShellApp)
DXE Example: a test in a UEFI event call back to check SPI/SMRAM status.
Shell Example: the SMM handler audit test has a shell-based app that interacts with an SMM handler to get information. The SMM paging audit test gathers information about both DXE and SMM. And the SMM paging functional test actually forces errors into SMM via a DXE driver.

Example Directory Tree

<PackageName>Pkg/
  ComponentY/
    ComponentY.inf
    ComponentY.c
    GoogleTest/
      ComponentYHostGoogleTest.inf    # Host-Based Test for Driver Module
      ComponentYGoogleTest.cpp
    UnitTest/
      ComponentYHostUnitTest.inf      # Host-Based Test for Driver Module
      ComponentYUnitTest.c

  Library/
    GeneralPurposeLibBase/
      ...

    GeneralPurposeLibSerial/
      ...

    SpecificLibDxe/
      SpecificLibDxe.c
      SpecificLibDxe.inf
      GoogleTest/                    # Host-Based Test for Specific Library Implementation
        SpecificLibDxeHostGoogleTest.cpp
        SpecificLibDxeHostGoogleTest.inf
      UnitTest/                      # Host-Based Test for Specific Library Implementation
        SpecificLibDxeHostUnitTest.c
        SpecificLibDxeHostUnitTest.inf
  Test/
    <Package>HostTest.dsc             # Host-Based Test Apps
    GoogleTest/
      InterfaceX
        InterfaceXHostGoogleTest.inf  # Host-Based App (should be in Test/<Package>HostTest.dsc)
        InterfaceXUnitTest.cpp        # Test Logic

      GeneralPurposeLib/              # Host-Based Test for any implementation of GeneralPurposeLib
        GeneralPurposeLibTest.cpp
        GeneralPurposeLibHostUnitTest.inf

    UnitTest/
      InterfaceX
        InterfaceXHostUnitTest.inf    # Host-Based App (should be in Test/<Package>HostTest.dsc)
        InterfaceXPeiUnitTest.inf     # PEIM Target-Based Test (if applicable)
        InterfaceXDxeUnitTest.inf     # DXE Target-Based Test (if applicable)
        InterfaceXSmmUnitTest.inf     # SMM Target-Based Test (if applicable)
        InterfaceXShellUnitTest.inf   # Shell App Target-Based Test (if applicable)
        InterfaceXUnitTest.c          # Test Logic

      GeneralPurposeLib/              # Host-Based Test for any implementation of GeneralPurposeLib
        GeneralPurposeLibTest.c
        GeneralPurposeLibHostUnitTest.inf

  <Package>Pkg.dsc          # Standard Modules and any Target-Based Test Apps (including in Test/)

Future Locations in Consideration

We don't know if these types will exist or be applicable yet, but if you write a support library or module that matches the following, please make sure they live in the correct place.

Code/Test Location
Host-Based Library Implementations Host-Based Implementations of common libraries (eg. MemoryAllocationLibHost) should live in the same package that declares the library interface in its .DEC file in the *Pkg/HostLibrary directory. Should have 'Host' in the name.
Host-Based Mocks and Stubs Mock and Stub libraries should live in the UefiTestFrameworkPkg/StubLibrary with either 'Mock' or 'Stub' in the library name.

If still in doubt...

Hop on GitHub and ask @corthon, @mdkinney, or @spbrogan. ;)

Copyright (c) Microsoft Corporation. SPDX-License-Identifier: BSD-2-Clause-Patent