# Schema Reference Pacemaker's XML schema has a version of its own, independent of the version of Pacemaker itself. ## Versioned Schema Evolution A versioned schema offers transparent backward and forward compatibility. - It reflects the timeline of schema-backed features (introduction, changes to the syntax, possibly deprecation) through the versioned stable schema increments, while keeping schema versions used by default by older Pacemaker versions untouched. - Pacemaker internally uses the latest stable schema version, and relies on supplemental transformations to promote cluster configurations based on older, incompatible schema versions into the desired form. ## Mapping Pacemaker Versions to Schema Versions | Pacemaker | Latest Schema | Changed | --------- | ------------- | ---------------------------------------------- | `2.1.5` | `3.9` | `alerts`, `constraints`, `nodes`, `nvset`, | | | `options`, `resources`, `rule` | `2.1.3` | `3.8` | `acls` | `2.1.0` | `3.7` | `constraints`, `resources` | `2.0.5` | `3.5` | `api`, `resources`, `rule` | `2.0.4` | `3.3` | `tags` | `2.0.1` | `3.2` | `resources` | `2.0.0` | `3.1` | `constraints`, `resources` | `1.1.18` | `2.10` | `resources`, `alerts` | `1.1.17` | `2.9` | `resources`, `rule` | `1.1.16` | `2.6` | `constraints` | `1.1.15` | `2.5` | `alerts` | `1.1.14` | `2.4` | `fencing` | `1.1.13` | `2.3` | `constraints` | `1.1.12` | `2.0` | `nodes`, `nvset`, `resources`, `tags`, `acls` | `1.1.8` | `1.2` | ## Schema generation Each logical portion of the schema goes into its own RNG file, named like `${base}-${X}.${Y}.rng`. `${base}` identifies the portion of the schema (e.g. constraints, resources); ${X}.${Y} is the latest schema version that contained changes in this portion of the schema. The complete, overall schema, `pacemaker-${X}.${Y}.rng`, is automatically generated from the other files via the Makefile. # Updating schema files # ## New features ## The current schema version is determined at runtime when crm\_schema\_init() scans the CRM\_SCHEMA\_DIRECTORY. It will have the form `pacemaker-${X}.${Y}` and the highest `${X}.${Y}` wins. ### Simple Additions When the new syntax is a simple addition to the previous one, create a new entry, incrementing `${Y}`. ### Feature Removal or otherwise Incompatible Changes When the new syntax is not a simple addition to the previous one, create a new entry, incrementing `${X}` and setting `${Y} = 0`. An XSLT file is also required that converts an old syntax to the new one and must be named `upgrade-${Xold}.${Yold}.xsl`. See `xml/upgrade-1.3.xsl` for an example. Since `xml/upgrade-2.10.xsl`, rather self-descriptive approach is taken, separating metadata of the replacements and other modifications to perform from the actual executive parts, which is leveraged, e.g., with the on-the-fly overview as obtained with `./regression.sh -X test2to3`. Also this was the first time particular key names of `nvpair`s, i.e. below the granularity of the schemas so far, received attention, and consequently, no longer expected names became systemically banned in the after-upgrade schemas, using `` construct in the data type specification pertaining the affected XML path. The implied complexity also resulted in establishing a new compound, stepwise transformation, alleviating the procedural burden from the core upgrade recipe. In particular, `id-ref` based syntactic simplification granted in the CIB format introduces nonnegligible internal "noise" because of the extra indirection encumbered with generally non-bijective character of such a scheme (context-dependent interpretation). To reduce this strain, a symmetric arrangement is introduced as a pair of _enter_/_leave_ (pre-upgrade/post-upgrade) transformations where the latter is meant to eventually reversibly restore what the former intentionally simplified (normalized) for upgrade transformation's peruse. It's optional (even the post-upgrade counterpart is optional alone) and depends on whether the suitable files are found along the upgrade transformation itself: e.g., for `upgrade-2.10.xsl`, such files are `upgrade-2.10-enter.xsl` and `upgrade-2.10-leave.xsl`. Note that unfolding + refolding `id-ref` shortcuts is just a practically imposed individual case of how to reversibly make the configuration space tractable in the upgrade itself, allowing for more sophistication down the road. ### General Procedure 1. Copy the most recent version of `${base}-*.rng` to `${base}-${X}.${Y}.rng`, such that the new file name increments the highest number of any schema file, not just the file being edited. 2. Commit the copy, e.g. `"Low: xml: clone ${base} schema in preparation for changes"`. This way, the actual change will be obvious in the commit history. 3. Modify `${base}-${X}.${Y}.rng` as required. 4. If required, add an XSLT file, and update `xslt\_SCRIPTS` in `xml/Makefile.am`. 5. Commit. 6. Run `make -C xml clean; make -C xml` to rebuild the schemas in the local 6. Run `make -C xml clean; make -C xml` to rebuild the schemas in the local source directory. 7. The CIB validity and upgrade regression tests will break after the schema is updated. Run `cts/cts-cli -s` to make the expected outputs reflect the changes made so far, and run `git diff` to ensure that these changes look sane. Finally, commit the changes. 8. Similarly, with the new major version `${X}`, it's advisable to refresh scheduler tests at some point. See the instructions in `cts/README.md`. ## Using a New Schema New features will not be available until the cluster administrator: 1. Updates all the nodes 2. Runs the equivalent of `cibadmin --upgrade --force` ## Random Notes From the source directory, run `make -C xml diff` to see the changes in the current schema (compared to the previous ones). Alternatively, if the intention is to grok the overall historical schema evolution, use `make -C xml fulldiff`.