This file focuses on information for those working with the .pytools
directory
directly or interested in lower-level details about how CI works.
If you just want to get started building code, visit Build Instructions on the TianoCore wiki.
Package | Windows VS2019 (IA32/X64) | Ubuntu GCC (IA32/X64/ARM/AARCH64) | Known Issues |
---|---|---|---|
ArmPkg | ✔️ | ||
ArmPlatformPkg | ✔️ | ||
ArmVirtPkg | SEE PACKAGE README | SEE PACKAGE README | |
CryptoPkg | ✔️ | ✔️ | Spell checking in audit mode |
DynamicTablesPkg | ✔️ | ✔️ | |
EmbeddedPkg | |||
EmulatorPkg | SEE PACKAGE README | SEE PACKAGE README | Spell checking in audit mode |
FatPkg | ✔️ | ✔️ | |
FmpDevicePkg | ✔️ | ✔️ | |
IntelFsp2Pkg | |||
IntelFsp2WrapperPkg | |||
MdeModulePkg | ✔️ | ✔️ | DxeIpl dependency on ArmPkg, Depends on StandaloneMmPkg, Spell checking in audit mode |
MdePkg | ✔️ | ✔️ | Spell checking in audit mode |
NetworkPkg | ✔️ | ✔️ | Spell checking in audit mode |
OvmfPkg | SEE PACKAGE README | SEE PACKAGE README | Spell checking in audit mode |
PcAtChipsetPkg | ✔️ | ✔️ | |
SecurityPkg | ✔️ | ✔️ | Spell checking in audit mode |
ShellPkg | ✔️ | ✔️ | Spell checking in audit mode, 3 modules are not being built by DSC |
SignedCapsulePkg | |||
SourceLevelDebugPkg | |||
StandaloneMmPkg | ✔️ | ✔️ | |
UefiCpuPkg | ✔️ | ✔️ | Spell checking in audit mode, 2 binary modules not being built by DSC |
UefiPayloadPkg | |||
UnitTestFrameworkPkg | ✔️ | ✔️ |
For more detailed status look at the test results of the latest CI run on the repo readme.
This Continuous integration and testing infrastructure leverages the TianoCore EDKII Tools PIP modules: library and extensions (with repos located here and here).
The primary execution flows can be found in the
.azurepipelines/Windows-VS2019.yml
and .azurepipelines/Ubuntu-GCC5.yml
files. These YAML files are consumed by the Azure Dev Ops Build Pipeline and
dictate what server resources should be used, how they should be configured, and
what processes should be run on them. An overview of this schema can be found
here.
Inspection of these files reveals the EDKII Tools commands that make up the primary processes for the CI build: 'stuart_setup', 'stuart_update', and 'stuart_ci_build'. These commands come from the EDKII Tools PIP modules and are configured as described below. More documentation on the tools can be found here and here.
Configuration of the CI process consists of (in order of precedence):
- command-line arguments passed in via the Pipeline YAML
- a per-package configuration file (e.g.
<package-name>.ci.yaml
) that is detected by the CI system in EDKII Tools. - a global configuration Python module (e.g.
CISetting.py
) passed in via the command-line
The global configuration file is described in this readme from the EDKII Tools documentation. This configuration is written as a Python module so that decisions can be made dynamically based on command line parameters and codebase state.
The per-package configuration file can override most settings in the global configuration file, but is not dynamic. This file can be used to skip or customize tests that may be incompatible with a specific package. Each test generally requires per package configuration which comes from this file.
The EDKII Tools environment (and by extension the ci) is designed to support easily and consistently running locally and in a cloud ci environment. To do that a few steps should be followed. Details of EDKII Tools can be found in the docs folder here
Quick notes:
- By default all CI plugins are opted in.
- Setting the plugin to
skip
as an argument will skip running the plugin. Examples:CompilerPlugin=skip
skip the build testGuidCheck=skip
skip the Guid checkSpellCheck=skip
skip the spell checker- etc.
- Setting the plugin to
- Detailed reports and logs per package are captured in the
Build
directory.
All CI tests are instances of EDKII Tools plugins. Documentation on the plugin system can be found here and here. Upon invocation, each plugin will be passed the path to the current package under test and a dictionary containing its targeted configuration, as assembled from the command line, per-package configuration, and global configuration.
Note: CI plugins are considered unique from build plugins and helper plugins, even though some CI plugins may execute steps of a build.
In the example, these plugins live alongside the code under test (in the
.pytool/Plugin
directory), but may be moved to the 'edk2-test' repo if that
location makes more sense for the community.
This scans all INF files from a package and confirms they are
listed in the package level DSC file. The test considers it an error if any INF
does not appear in the Components
section of the package-level DSC (indicating
that it would not be built if the package were built). This is critical because
much of the CI infrastructure assumes that all modules will be listed in the DSC
and compiled.
This test will ignore INFs in the following cases:
- When
MODULE_TYPE
=HOST_APPLICATION
- When a Library instance only supports the
HOST_APPLICATION
environment
This test scans all INF files from a package for those related to host
based unit tests and confirms they are listed in the unit test DSC file for the package.
The test considers it an error if any INF meeting the requirements does not appear
in the Components
section of the unit test DSC. This is critical because
much of the CI infrastructure assumes that modules will be listed in the DSC
and compiled.
This test will only require INFs in the following cases:
- When
MODULE_TYPE
=HOST_APPLICATION
- When a Library instance explicitly supports the
HOST_APPLICATION
environment
Once the Module Inclusion Test has verified that all modules would be built if all package-level DSCs were built, the Code Compilation Test simply runs through and builds every package-level DSC on every toolchain and for every architecture that is supported. Any module that fails to build is considered an error.
A test that compiles the dsc for host based unit test apps. On Windows this will also enable a build plugin to execute that will run the unit tests and verify the results.
These tools will be invoked on any CI pass that includes the NOOPT target. In order for these tools to do their job, the package and tests must be configured in a particular way...
For example, looking at the MdeModulePkg.ci.yaml
config file, there are two
config options that control HostBased test behavior:
## options defined .pytool/Plugin/HostUnitTestCompilerPlugin
"HostUnitTestCompilerPlugin": {
"DscPath": "Test/MdeModulePkgHostTest.dsc"
},
This option tell the test builder to run. The test builder needs to know which modules in this package are host-based tests, so that DSC path is provided.
The HostBased DSC for MdeModulePkg
is located at
MdeModulePkg/Test/MdeModulePkgHostTest.dsc
.
To add automated host-based unit test building to a new package, create a
similar DSC. The new DSC should make sure to have the NOOPT
BUILD_TARGET
and should include the line:
!include UnitTestFrameworkPkg/UnitTestFrameworkPkgHost.dsc.inc
All of the modules that are included in the Components
section of this
DSC should be of type HOST_APPLICATION.
This test works on the collection of all packages rather than an individual package. It looks at all FILE_GUIDs and GUIDs declared in DEC files and ensures that they are unique for the codebase. This prevents, for example, accidental duplication of GUIDs when using an existing INF as a template for a new module.
This test compares the list of all packages used in INFs files for a given package against a list of "allowed dependencies" in plugin configuration for that package. Any module that depends on a disallowed package will cause a test failure.
This test scans at all library header files found in the Library
folders in
all of the package's declared include directories and ensures that all files
have a matching LibraryClass declaration in the DEC file for the package. Any
missing declarations will cause a failure.
This test scans all files in a package to make sure that there are no invalid Unicode characters that may cause build errors in some character sets/localizations.
This test runs a spell checker on all files within the package. This is done
using the NodeJs cspell tool. For details check .pytool/Plugin/SpellCheck
.
For this plugin to run during ci you must install nodejs and cspell and have
both available to the command line when running your CI.
Install
-
Install nodejs from https://nodejs.org/en/
-
Install cspell
- Open cmd prompt with access to node and npm
- Run
npm install -g cspell
More cspell info: https://github.com/streetsidesoftware/cspell
Scans all new added files in a package to make sure code is contributed under BSD-2-Clause-Patent.
Run the Ecc tool on the package. The Ecc tool is available in the BaseTools package. It checks that the code complies to the EDKII coding standard.
Runs the Uncrustify application to check for coding standard compliance issues.
Scopes are how the PyTool ext_dep, path_env, and plugins are activated. Meaning that if an invocable process has a scope active then those ext_dep and path_env will be active. To allow easy integration of PyTools capabilities there are a few standard scopes.
Scope | Invocable | Description |
---|---|---|
global | edk2_invocable++ - should be base_abstract_invocable | Running an invocables |
global-win | edk2_invocable++ | Running on Microsoft Windows |
global-nix | edk2_invocable++ | Running on Linux based OS |
edk2-build | This indicates that an invocable is building EDK2 based UEFI code | |
cibuild | set in .pytool/CISettings.py | Suggested target for edk2 continuous integration builds. Tools used for CiBuilds can use this scope. Example: asl compiler |
host-based-test | set in .pytool/CISettings.py | Turns on the host based tests and plugin |
host-test-win | set in .pytool/CISettings.py | Enables the host based test runner for Windows |
- PatchCheck tests as plugins
- MacOS/xcode support
- Clang/LLVM support
- Visual Studio AARCH64 and ARM support
- BaseTools C tools CI/PR and binary release process
- BaseTools Python tools CI/PR process
- Extensible private/closed source platform reporting
- UEFI SCTs
- Other automation