This document lists a set of policies that you should apply when adding or updating a port recipe. It is intended to serve the role of Debian's Policy Manual, Homebrew's Maintainer Guidelines, and Homebrew's Formula Cookbook.
Whenever possible, separate changes into multiple PRs. This makes them significantly easier to review and prevents issues with one set of changes from holding up every other change.
For example, avoid reformatting or renaming variables in portfiles that otherwise have no reason to be modified for the issue at hand. However, if you need to modify the file for the primary purpose of the PR (updating the library), then obviously beneficial changes like fixing typos are appreciated!
A good service to check many at once is Repology. If the library you are adding could be confused with another one, consider renaming to make it clear. We prefer when names are longer and/or unlikely to conflict with any future use of the same name. If the port refers to a library on GitHub, a good practice is to prefix the name with the organization if there is any chance of confusion.
GitHub Draft PRs are a great way to get CI or human feedback on work that isn't yet ready to merge. Most new PRs should be opened as drafts and converted to normal PRs once the CI passes.
More information about GitHub Draft PRs: https://github.blog/2019-02-14-introducing-draft-pull-requests/
At this time, the following helpers are deprecated:
vcpkg_extract_source_archive()
should be replaced byvcpkg_extract_source_archive_ex()
vcpkg_apply_patches()
should be replaced by thePATCHES
arguments to the "extract" helpers (e.g.vcpkg_from_github()
)vcpkg_build_msbuild()
should be replaced byvcpkg_install_msbuild()
vcpkg_copy_tool_dependencies()
should be replaced byvcpkg_copy_tools()
vcpkg_configure_cmake
should be replaced byvcpkg_cmake_configure()
after removingPREFER_NINJA
(from portvcpkg-cmake
)vcpkg_build_cmake
should be replaced byvcpkg_cmake_build()
(from portvcpkg-cmake
)vcpkg_install_cmake
should be replaced byvcpkg_cmake_install()
(from portvcpkg-cmake
)vcpkg_fixup_cmake_targets
should be replaced byvcpkg_cmake_config_fixup
(from portvcpkg-cmake-config
)
Some of the replacement helper functions are in "tools ports" to allow consumers to pin their
behavior at specific versions, to allow locking the behavior of the helpers at a particular
version. Tools ports need to be added to your port's "dependencies"
, like so:
{
"name": "vcpkg-cmake",
"host": true
},
{
"name": "vcpkg-cmake-config",
"host": true
}
Ideally, portfiles should be short, simple, and as declarative as possible.
Remove any boiler plate comments introduced by the create
command before submitting a PR.
Ports must not change their behavior based on which ports are already installed in a form that would change which contents that port installs. For example, given:
> vcpkg install a
> vcpkg install b
> vcpkg remove a
and
> vcpkg install b
the files installed by b
must be the same, regardless of influence by the previous installation of a
. This means that ports must not try to detect whether something is provided in the installed tree by another port before taking some action. A specific and common cause of such "path dependent" behavior is described below in "When defining features, explicitly control dependencies."
In the entire vcpkg system, no two ports a user is expected to use concurrently may provide the same file. If a port tries to install a file already provided by another file, installation will fail. If a port wants to use an extremely common name for a header, for example, it should place those headers in a subdirectory rather than in include
.
Features must be treated as additive functionality. If port[featureA] installs and port[featureB] installs, then port[featureA,featureB] must install. Moreover, if a second port depends on [featureA] and a third port depends on [featureB], installing both the second and third ports should have their dependencies satisfied.
Libraries in this situation must choose one of the available options as expressed in vcpkg, and users who want a different setting must use overlay ports at this time.
Existing examples we would not accept today retained for backwards compatibility:
libgit2
,libzip
,open62541
all have features for selecting a TLS or crypto backend. Note thatcurl
has different crypto backend options but allows selecting between them at runtime, meaning the above tenet is maintained.darknet
hasopencv2
,opencv3
, features to control which version of opencv to use for its dependencies.
Notwithstanding the above, if there is a preview branch or similar where the preview functionality has a high probability of not disrupting the non-preview functionality (for example, no API removals), a feature is acceptable to model this setting.
Examples:
- The Azure SDKs (of the form
azure-Xxx
) have apublic-preview
feature. imgui
has anexperimental-docking
feature which engages their preview docking branch which uses a merge commit attached to each of their public numbered releases.
If a consumer is depending directly upon a library, they can list out any desired features easily (library[feature1,feature2]
). However, if a consumer does not know they are using a library, they cannot list out those features. If that hidden library is like libarchive
where features are adding additional compression algorithms (and thus behaviors) to an existing generic interface, default features offer a way to ensure a reasonably functional transitive library is built even if the final consumer doesn't name it directly.
If the feature adds additional APIs (or executables, or library binaries) and doesn't modify the behavior of existing APIs, it should be left off by default. This is because any consumer which might want to use those APIs can easily require it via their direct reference.
If in doubt, do not mark a feature as default.
If a consumer of a port depends on only the core functionality of that port, with high probability they must not be broken by turning on the feature. This is even more important when the alternative is not directly controlled by the consumer, but by compiler settings like /std:c++17
/ -std=c++17
.
Existing examples we would not accept today retained for backwards compatibility:
redis-plus-plus[cxx17]
controls a polyfill but does not bake the setting into the installed tree.ace[wchar]
changes all APIs to acceptconst wchar_t*
rather thanconst char*
.
A feature may replace polyfills with aliases provided that replacement is baked into the installed tree
Notwithstanding the above, ports may remove polyfills with a feature, as long as:
- Turning on the feature changes the polyfills to aliases of the polyfilled entity
- The state of the polyfill is baked into the installed headers, such that ABI mismatch "impossible" runtime errors are unlikely
- It is possible for a consumer of the port to write code which works in both modes, for example by using a typedef which is either polyfilled or not
Example:
abseil[cxx17]
changesabsl::string_view
to a replacement orstd::string_view
; the patch https://github.com/microsoft/vcpkg/blob/981e65ce0ac1f6c86e5a5ded7824db8780173c76/ports/abseil/fix-cxx-standard.patch implements the baking requirement
If it's critical to expose the underlying alternatives, we recommend providing messages at build time to instruct the user on how to copy the port into a private overlay:
set(USING_DOG 0)
message(STATUS "This version of LibContosoFrobnicate uses the Kittens backend. To use the Dog backend instead, create an overlay port of this with USING_DOG set to 1 and the `kittens` dependency replaced with `dog`.")
message(STATUS "This recipe is at ${CMAKE_CURRENT_LIST_DIR}")
message(STATUS "See the overlay ports documentation at https://github.com/microsoft/vcpkg/blob/master/docs/specifications/ports-overlay.md")
Do not use embedded copies of libraries. All dependencies should be split out and packaged separately so they can be updated and maintained.
When multiple buildsystems are available, prefer using CMake.
Additionally, when appropriate, it can be easier and more maintainable to rewrite alternative buildsystems into CMake using file(GLOB)
directives.
Examples: abseil
By default, vcpkg_configure_cmake()
will pass in the appropriate setting for BUILD_SHARED_LIBS
,
however for libraries that don't respect that variable, you can switch on VCPKG_LIBRARY_LINKAGE
:
string(COMPARE EQUAL "${VCPKG_LIBRARY_LINKAGE}" "static" KEYSTONE_BUILD_STATIC)
string(COMPARE EQUAL "${VCPKG_LIBRARY_LINKAGE}" "dynamic" KEYSTONE_BUILD_SHARED)
vcpkg_configure_cmake(
SOURCE_PATH ${SOURCE_PATH}
PREFER_NINJA
OPTIONS
-DKEYSTONE_BUILD_STATIC=${KEYSTONE_BUILD_STATIC}
-DKEYSTONE_BUILD_SHARED=${KEYSTONE_BUILD_SHARED}
)
When defining a feature that captures an optional dependency, ensure that the dependency will not be used accidentally when the feature is not explicitly enabled.
if ("zlib" IN_LIST FEATURES)
set(CMAKE_DISABLE_FIND_PACKAGE_ZLIB OFF)
else()
set(CMAKE_DISABLE_FIND_PACKAGE_ZLIB ON)
endif()
vcpkg_configure_cmake(
SOURCE_PATH ${SOURCE_PATH}
PREFER_NINJA
OPTIONS
-DCMAKE_DISABLE_FIND_PACKAGE_ZLIB=${CMAKE_DISABLE_FIND_PACKAGE_ZLIB}
)
The snippet below using vcpkg_check_features()
is equivalent, see the documentation.
vcpkg_check_features(OUT_FEATURE_OPTIONS FEATURE_OPTIONS
INVERTED_FEATURES
"zlib" CMAKE_DISABLE_FIND_PACKAGE_ZLIB
)
vcpkg_configure_cmake(
SOURCE_PATH ${SOURCE_PATH}
PREFER_NINJA
OPTIONS
${FEATURE_OPTIONS}
)
Note that ZLIB
in the above is case-sensitive. See the cmake documentation for more details.
A lib is considered conflicting if it does any of the following:
- Define
main
- Define malloc
- Define symbols that are also declared in other libraries
Conflicting libs are typically by design and not considered a defect. Because some build systems link against everything in the lib directory, these should be moved into a subdirectory named manual-link
.
When adding a new port, use the new manifest syntax for defining a port;
you may also change over to manifests when modifying an existing port.
You may do so easily by running the vcpkg format-manifest
command, which will convert existing CONTROL
files into manifest files. Do not convert CONTROL files that have not been modified.
See our versioning documentation for a full explanation of our conventions.
Vcpkg uses this field to determine whether a given port is out-of-date and should be changed whenever the port's behavior changes.
Our convention is to use the "port-version"
field for changes to the port that don't change the upstream version, and to reset the "port-version"
back to zero when an update to the upstream version is made.
For Example:
- Zlib's package version is currently
1.2.1
, with no explicit"port-version"
(equivalent to a"port-version"
of0
). - You've discovered that the wrong copyright file has been deployed, and fixed that in the portfile.
- You should update the
"port-version"
field in the manifest file to1
.
See our manifest files document for a full explanation of our conventions.
Vcpkg uses a set of metadata files to power its versioning feature. These files are located in the following locations:
${VCPKG_ROOT}/versions/baseline.json
, (this file is common to all ports) and${VCPKG_ROOT}/versions/${first-letter-of-portname}-/${portname}.json
(one per port).
For example, for zlib
the relevant files are:
${VCPKG_ROOT}/versions/baseline.json
${VCPKG_ROOT}/versions/z-/zlib.json
We expect that each time you update a port, you also update its version files.
The recommended method to update these files is to run the x-add-version
command, e.g.:
vcpkg x-add-version zlib
If you're updating multiple ports at the same time, instead you can run:
vcpkg x-add-version --all
To update the files for all modified ports at once.
NOTE: These commands require you to have committed your changes to the ports before running them. The reason is that the Git SHA of the port directory is required in these version files. But don't worry, the x-add-version
command will warn you if you have local changes that haven't been committed.
See our versioning specification and registries specification to learn how vcpkg interacts with these files.
It is preferable to set options in a call to vcpkg_configure_xyz()
over patching the settings directly.
Common options that allow avoiding patching:
- [MSBUILD]
<PropertyGroup>
settings inside the project file can be overridden via/p:
parameters - [CMAKE] Calls to
find_package(XYz)
in CMake scripts can be disabled via-DCMAKE_DISABLE_FIND_PACKAGE_XYz=ON
- [CMAKE] Cache variables (declared as
set(VAR "value" CACHE STRING "Documentation")
oroption(VAR "Documentation" "Default Value")
) can be overridden by just passing them in on the command line as-DVAR:STRING=Foo
. One notable exception is if theFORCE
parameter is passed toset()
. See also the CMakeset
documentation
Some variables prefixed with VCPKG_<VARIABLE>
have an equivalent CMAKE_<VARIABLE>
.
However, not all of them are passed to the internal package build (see implementation: Windows toolchain).
Consider the following example:
set(VCPKG_C_FLAGS "-O2 ${VCPKG_C_FLAGS}")
set(VCPKG_CXX_FLAGS "-O2 ${VCPKG_CXX_FLAGS}")
Using vcpkg
's built-in toolchains this works, because the value of VCPKG_<LANG>_FLAGS
is forwarded to the appropriate CMAKE_LANG_FLAGS
variable. But, a custom toolchain that is not aware of vcpkg
's variables will not forward them.
Because of this, it is preferable to patch the buildsystem directly when setting CMAKE_<LANG>_FLAGS
.
When making changes to a library, strive to minimize the final diff. This means you should not reformat the upstream source code when making changes that affect a region. Also, when disabling a conditional, it is better to add a AND FALSE
or && 0
to the condition than to delete every line of the conditional.
This helps to keep the size of the vcpkg repository down as well as improves the likelihood that the patch will apply to future code versions.
The purpose of patching in vcpkg is to enable compatibility with compilers, libraries, and platforms. It is not to implement new features in lieu of following proper Open Source procedure (submitting an Issue/PR/etc).
When submitting a new port, check for any options like BUILD_TESTS
or WITH_TESTS
or POCO_ENABLE_SAMPLES
and ensure the additional binaries are disabled. This minimizes build times and dependencies for the average user.
Optionally, you can add a test
feature which enables building the tests, however this should not be in the Default-Features
list.
Unless the author of the library is already using it, we should not use this CMake functionality because it interacts poorly with C++ templates and breaks certain compiler features. Libraries that don't provide a .def file and do not use __declspec() declarations simply do not support shared builds for Windows and should be marked as such with vcpkg_check_linkage(ONLY_STATIC_LIBRARY)
.
This means that if the upstream library has different names in release and debug (libx versus libxd), then the debug library should not be renamed to libx
. Vice versa, if the upstream library has the same name in release and debug, we should not introduce a new name.
Important caveat:
- Static and shared variants often should be renamed to a common scheme. This enables consumers to use a common name and be ignorant of the downstream linkage. This is safe because we only make one at a time available.
Note that if a library generates CMake integration files (foo-config.cmake
), renaming must be done through patching the CMake build itself instead of simply calling file(RENAME)
on the output archives/LIBs.
Finally, DLL files on Windows should never be renamed post-build because it breaks the generated LIBs.
We require the C++ code inside vcpkg to follow the clang-format, if you change them. Please perform the following steps after modification:
- Use Visual Studio:
- Configure your clang-format tools.
- Open the modified file.
- Use shortcut keys Ctrl+K, Ctrl+D to format the current file.
- Use tools:
- Install llvm clang-format
- Run command:
> LLVM_PATH/bin/clang-format.exe -style=file -i changed_file.cpp
We require that the manifest file be formatted. Use the following command to format all manifest files:
> vcpkg format-manifest --all
While portfile.cmake
's and CMakeLists.txt
's share a common syntax and core CMake language constructs, portfiles run in "Script Mode", whereas CMakeLists.txt
files run in "Build Mode" (unofficial term). The most important difference between these two modes is that "Script Mode" does not have a concept of "Target" -- any behaviors that depend on the "target" machine (CMAKE_CXX_COMPILER
, CMAKE_EXECUTABLE_SUFFIX
, CMAKE_SYSTEM_NAME
, etc) will not be correct.
Portfiles have direct access to variables set in the triplet file, but CMakeLists.txt
s do not (though there is often a translation that happens -- VCPKG_LIBRARY_LINKAGE
versus BUILD_SHARED_LIBS
).
Portfiles and CMake builds invoked by portfiles are run in different processes. Conceptually:
+----------------------------+ +------------------------------------+
| CMake.exe | | CMake.exe |
+----------------------------+ +------------------------------------+
| Triplet file | ====> | Toolchain file |
| (x64-windows.cmake) | | (scripts/buildsystems/vcpkg.cmake) |
+----------------------------+ +------------------------------------+
| Portfile | ====> | CMakeLists.txt |
| (ports/foo/portfile.cmake) | | (buildtrees/../CMakeLists.txt) |
+----------------------------+ +------------------------------------+
To determine the host in a portfile, the standard CMake variables are fine (CMAKE_HOST_WIN32
).
To determine the target in a portfile, the vcpkg triplet variables should be used (VCPKG_CMAKE_SYSTEM_NAME
).
See also our triplet documentation for a full enumeration of possible settings.