Userland Consolidation Packaging Guidelines. Each component that integrates into the Userland consolidation must have at least one package manifest that describes the content to be delivered. In some cases components *may* deliver through multiple packages. Canonical component package manifests must be placed in the component's build directory. They also must be named *.p5m. In order to understand what must go in the content of a package manifest, it's useful to have an understanding of how a canonical manifest is transformed into a final manifest used for package publication. Manifest transformation takes the following basic path: canonical manifest (.../{component}/{component}.p5m) | v mogrified manifest (.../{component}/{build-dir}/manifest-$(MACH)-{component}.mogrified) | v mangled manifest file contents (.../{component}/{build-dir}/manifest-$(ARCH)-{component}.mangled) | v dependencies generated (.../{component}/{build-dir}/manifest-$(MACH)-{component}.depend) | v dependencies resolved (.../{component}/{build-dir}/manifest-$(MACH)-{component}.depend.res) | v manifest validation (.../{component}/{build-dir}/.linted-$(MACH)) | v publication manifest (.../{component}/{build-dir}/manifest-$(MACH)-{component}.published) | v publication Canonical Manifest The canonical manifest contains actions that can't otherwise be generated automatically from the data encapsulated in the component Makefile, gate transformations, build tree, and packaging tools. This includes actions for license information, some path related attributes, legacy actions, non-discoverable dependencies, users, groups, drivers, and others. Actions that are associated with objects that are specific to a single architecture should be tagged with a 'variant.arch' attribute specific to the architecture that applied to the action. Ex: file path=/usr/lib/$(MACH64)/libx86onlybits.so variant.arch=i386 Actions for editable files must include an appropriate 'preserve' attribute: file path=etc/gnu/a2ps.cfg preserve=true mode=0644 license actions should be placed in the canonical manifest. Mogrified Manifest The canonical manifest is combined with a set of the transforms in $(WS_TOP)/transforms, and a set of macros to more complete package manifest using pkgmogrify(1). The transforms apply default attributes to the various actions in the canonical manifest(s). More detail about the attributes can be found in the transform file themselves. The macros applied at the time of mogrification are as follows: $(MACH) $(MACH32) $(MACH64) $(PUBLISHER) $(CONSOLIDATION) $(BUILD_VERSION) $(SOLARIS_VERSION) $(OS_VERSION) $(IPS_COMPONENT_VERSION) $(COMPONENT_VERSION) $(COMPONENT_PROJECT_URL) $(COMPONENT_ARCHIVE_URL) Dependencies Generated The mogrified manifest and the prototype install tree are passed through pkgdepend(1) to generate a set of dependencies for the package content. These dependencies are only those that "pkgdepend generate" can determine on its own. Additional dependencies that cannot be automatically determined by pkgdepend(1) should be placed in the canonical manifest. Statically defined dependencies should be described in a canonical manifest in an unresolved form (ie. the form generated by "pkgdepend generate"). Ex: depend fmri=__TBD pkg.debug.depend.file=etc/passwd \ pkg.debug.reason=usr/bin/vipw type=require depend fmri=__TBD pkg.debug.depend.file=sh \ pkg.debug.depend.path=usr/bin \ pkg.debug.depend.reason=usr/bin/psmandup \ pkg.debug.depend.type=script type=require This will allow the next step to resolve all dependencies to their proper package(s). Dependencies Resolved The manifest with unresolved dependencies is passed through pkgdepend(1) again to resolve dependencies against the package repositories. The result is a manifest that is suitable for publication. All these manifests are processed together in a single step, which is more efficient than resolving dependencies in each manifest separately. While each manifest ends up with a .depend.res copy in the build directory, the umbrella dependency resolution target is {build-dir}/.resolved-$(MACH). The resolution step is also set up to use the -e flag to pkgdepend resolve, which limits the set of packages it looks at to resolve the dependencies it generated in the previous step. This makes the resolution step a great deal faster, but requires that you include a static list of these packages in your component Makefile REQUIRED_PACKAGES macro. You can automatically add REQURIED_PACKAGES settings for the packages used in dependency resolution by running "gmake REQUIRED_PACKAGES". Once you have done so, you should manually verify the Makefile additions. Having extra packages in there is safe. This list is kept as the REQUIRED_PACKAGES list in your component Makefile, which you must append to (as shared-rules introduce some packages there themselves for your benefit). To test, run "gmake clean" and re-publish. Note that there is a possibility the list of dependencies will be different on different architectures, so you should run this on both sparc and x86, and combine the two lists. Please keep the lists sorted. Manifest Validation The resolved manifest(s) and prototype install tree are passed through a set of validations. This includes running pkglint(1), comparing the manifest content to the prototype install tree, and validation of the file content of the prototype install tree. Any anomalies are reported. Content validation is performed by extension to pkglint(1) in $(WS_TOP)/tools/python/userland-lint Publication. Once manifest validation has occurred, the package(s) is/are finally published to the workspace package repository. # vi:set fdm=marker expandtab ts=4: