// file : doc/packaging.cli // license : MIT; see accompanying LICENSE file "\name=build2-packaging-guide" "\subject=toolchain" "\title=Packaging Guide" // NOTES // // - Maximum
line is 70 characters. // " \h0#preface|Preface| This document provides guidelines for converting third-party projects to the \c{build2} build system and making them available as packages from \l{https://cppget.org cppget.org}, the \c{build2} community's central package repository. For additional information, including documentation for individual \c{build2} toolchain components, man pages, HOWTOs, etc., refer to the project \l{https://build2.org/doc.xhtml Documentation} page. \N|This document is a work in progress and is incomplete.| \h1#dont-do|What Not to Do| \h#dont-from-scratch|Don't write \c{buildfile}s from scratch, use \c{bdep-new}| Unless you have good reasons not to, create the initial project layout automatically using \l{bdep-new(1)}, then tweak it if necessary and fill with upstream source code. The main rationale here is that there are many nuances in getting the build right and auto-generated \c{buildfile}s had years of refinement and fine-tuning. The familiar structure also makes it easier for others to understand your build, for example while reviewing your package submission. The \l{bdep-new(1)} command supports a wide variety of \l{bdep-new.xhtml#src-layout source layouts}. While it may take a bit of time to understand the customization points necessary to achieve the desired layout for your first package, this will pay off in spades when you work on converting subsequent packages. The recommended sequence of steps is as follows: \ol| \li|Study the upstream source layout. We want to stay as close to upstream as possible since this has the best chance of producing an issues-free result (see \l{#dont-change-upstream Don't change upstream source code layout} for details).| \li|Craft and execute the \l{bdep-new(1)} command line necessary to achieve the upstream layout.| \li|Study the auto-generated \c{buildfile}s for things that don't fit and need to change. But don't rush to start manually editing the result. First get an overview of the required changes and then check if it's possible to achieve these changes automatically using one of \l{bdep-new(1)} sub-options. For example, if you see that the generated project assumes the wrong C++ file extensions, these can be changed with \c{--lang|-l} sub-options.| \li|Once you have squeezed as much as possible out of \l{bdep-new(1)}, it's time for manual customizations. These would normally include: \ul| \li|Replace generated source code with upstream, normally as symlinks from the \c{upstream/} \c{git} submodule.| \li|Tweak source subdirectory \c{buildfile} that builds the main target (library, executable).| \li|Add tests and, if necessary, examples.| \li|Tweak \c{manifest} (in particular the \c{version}, \c{summary}, and \c{license} values).| \li|Fill in \c{README.md}.||| | \h#dont-change-upstream|Don't change upstream source code layout| It's a good idea to stay as close to the upstream's source code layout as possible. This has the best chance of giving us a build without any compile errors since the header inclusion in the project can be sensitive to this layout. This also makes it easier for upstream to adopt the \c{build2} build. Sometimes, however, there are good reasons for deviating from upstream, especially in cases where upstream is clearly following bad practices, for example installing generically-named headers without a library prefix. If you do decide to change the layout, it's usually less disruptive (to the build) to rearrange things at the outer levels than at the inner. For example, it should normally be possible to move/rename the top-level \c{tests/} directory or to place the library source directory into a subdirectory. \h#dont-forget-update-manifest|Don't forget to update \c{manifest} values| After \l{#dont-from-scratch generating the project template with \c{bdep-new}}, don't forget to update at least the key values in the generated \c{manifest}: \l{#dont-forget-update-manifest-version \c{version}}, \l{#dont-forget-update-manifest-license \c{license}}, and \l{#dont-forget-update-manifest-summary \c{summary}}. \h2#dont-forget-update-manifest-version|Don't forget to update \c{manifest} value \c{version}| For \c{version}, use the upstream version directly if it is semver (or semver-like, that is, has three version components). Otherwise, see \l{https://github.com/build2/HOWTO/blob/master/entries/handle-projects-which-dont-use-semver.md How do I handle projects that don't use semantic versioning?} and \l{https://github.com/build2/HOWTO/blob/master/entries/handle-projects-which-dont-use-version.md How do I handle projects that don't use versions at all?} \h2#dont-forget-update-manifest-license|Don't forget to update \c{manifest} value \c{license}| For \c{license}, use the \l{https://spdx.org/licenses/ SPDX license ID} if at all possible. If multiple licenses are involved, use the SPDX License expression. See the \l{https://build2.org/bpkg/doc/build2-package-manager-manual.xhtml#manifest-package-license \c{license} manifest value} documentation for details and the list of the most commonly used SPDX license IDs. \h2#dont-forget-update-manifest-summary|Don't forget to update \c{manifest} value \c{summary}| For \c{summary} use a brief description of the functionality provided by the package. Less than 70 characters is a good target to aim for. Don't capitalize subsequent words unless proper nouns and omit the trailing dot. For example: \ summary: Vim xxd hexdump utility \ Omit weasel words such as \"modern\", \"simple\", \"fast\", \"small\", etc., since they don't convey anything specific. Omit \"header-only\" or \"single-header\" for C/C++ libraries since at least in the context of \c{build2} it does not imply any advantage. If upstream does not offer a sensible summary, the following template is recommended for libraries: \ summary:C library summary: C++ library \ For example: \ summary: Event notification C library summary: Validating XML parsing and serialization C++ library \ If the project consists of multiple packages it may be tempting to name each package in terms of the overall project name, for example: \ summary: libigl's core module \ This doesn't give the user any clue about what functionality is provided unless they find out what \c{libigl} is about. Better: \ summary: Geometry processing C++ library, core module \ If you follow the above pattern, then to produce a summary for external tests or examples packages simply add \"tests\" or \"examples\" at the end, for example: \ summary: Event notification C library tests summary: Geometry processing C++ library, core module examples \ \h#dont-header-only|Don't make a library header-only if it can be compiled| Some libraries offer two alternative modes: header-only and compiled. Unless there are good reasons not to, a \c{build2} build of such a library should use the compiled mode. \N|Some libraries use the \i{precompiled} term to describe the non-header-only mode. We don't recommend using this term in the \c{build2} build since it has a strong association with precompiled headers and can therefore be confusing. Instead, use the \i{compiled} term.| The main rationale here is that a library would not be offering a compiled mode if there were no benefits (usually faster compile times of library consumers) and there is no reason not to take advantage of it in the \c{build2} build. There are, however, reasons why a compiled mode cannot be used, the most common of which are: \ul| \li|The compiled mode is not well maintained/tested by upstream and therefore offers inferior user experience.| \li|The compiled mode does not work on some platforms, usually Windows due to the lack of symbol export support (but see \l{b##cc-auto-symexport Automatic DLL Symbol Exporting}).| \li|Uses of the compiled version of the library requires changes to the library consumers, for example, inclusion of different headers.| | If a compiled mode cannot be always used, then it may be tempting to support both modes potentially making the mode user-configurable. Unless there are strong reasons to, you should resist this temptation and, if the compiled mode is not universally usable, then use the header-only mode everywhere. The main rationale here is that variability adds complexity which makes the result more prone to bugs, more difficult to use, and harder to review and maintain. If you really want to have the compiled mode, then the right way to do it is to work with upstream to fix any issues that prevent its use in \c{build2}. There are, however, reasons why supporting both mode may be needed, the most common of which are: \ul| \li|The library is widely used in both modes but switching from one mode to the other requires changes to the library consumers (for example, inclusion of different headers). In this case only supporting one mode would mean not supporting a large number of library consumers.| \li|The library consists of a large number of independent components and its common for applications to only use a small subset of them. On the other hand, compiling all of them in the compiled mode takes a substantial amount of time. (Note that this can also be addressed by making the presence of optional components user-configurable.)| | \h#dont-main-target-root-buildfile|Don't build your main targets in root \c{buldfile}| It may be tempting to have your main targets (libraries, executables) in the root \c{buildfile}, especially if it allows you to symlink entire directories from \c{upstream/} (which is not possible if you have to have a \c{buildfile} inside). However, this is a bad idea except for the simplest projects. Firstly, this quickly gets messy since you have to combine managing \c{README}s, \c{LICENSE}s, and subdirectories with you main target builds. But, more importantly, this means that when you main target is imported (and thus the \c{buildfile} that defines this target must be loaded), your entire project will be loaded, including any \c{tests/} and \c{examples/} subproject, which is wasteful. Note also that it's easy to continue symlinking entire directories from \c{upstream/} without moving everything to the root \c{buildfile} by simply creating another subdirectory. Let's look at a concrete example. Here is the directory structure where everything is in the root \c{buildfile}: \ libigl-core/ ├── igl/ -> upstream/igl/ ├── tests/ └── buildfile # Defines lib{igl-core}. \ And here is the alternative structure where we have added the \c{libigl-core} subdirectory with its own \c{buildfile}: \ libigl-core/ ├── libigl-core/ │ ├── igl/ -> ../upstream/igl/ │ └── buildfile # Defines lib{igl-core}. ├── tests/ └── buildfile \ Below is the \l{bdep-new(1)} invocation that can be used to automatically create this alternative structure (see \l{bdep-new.xhtml#src-layout SOURCE LAYOUT} for details): \ $ bdep new -t lib,prefix=libigl-core,no-subdir,no-version libigl-core \ \h1#faq|Packaging FAQ| \h#faq-publish-stage|Where to publish if package requires staged toolchain?| If your package requires the \l{https://build2.org/community.xhtml#stage staged toolchain}, for example, because it needs a feature or bugfix that is not yet available in the released toolchain, then you won't be able to publish it to \c{cppget.org}. Specifically, if your package has the accurate \c{build2} version constraint and you attempt to publish it, you will get an error like this: \ error: package archive is not valid info: unable to satisfy constraint (build2 >= 0.17.0-) for package foo info: available build2 version is 0.16.0 \ There are three alternative ways to proceed in this situation: \ol| \li|Wait until the next release and then publish the package to \c{cppget.org}.| \li|If the requirement for the staged toolchain is \"minor\", that is, it doesn't affect the common functionality of the package or only affects a small subset of platforms/compilers, then you can lower the toolchain version requirement and publish the package to \c{cppget.org}. For example, if you require the staged toolchain because of a bugfix that only affects one platform, it doesn't make sense to delay publishing the package since it is perfectly usable on all the platforms in the meantime.| \li|Publish it to \l{https://queue.stage.build2.org queue.stage.build2.org}, the staging package repository. This repository contain new packages that require the staged toolchain to work and which will be automatically moved to \c{cppget.org} once the staged version is released. The other advantage of publishing to this repository (besides not having to remember to manually publish the package once the staged version is released) is that your package becomes available from an archive repository (which is substantially faster than a \c{git} repository). To publish to this repository, use the following \c{bdep-publish} command line: \ $ bdep publish --repository=https://stage.build2.org ... \ || "