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Questions

Assuming at least some of packages we need to ship with SIMP already belong to modular repository streams, how can/should we handle:

Building SIMP RPM distributions (pkglist.txt + packages.yaml, repositories, ISOs, etc.,)

80% Confidence it’s Possible — but it will be complicated and hacky

  • The current methods of downloading external packages AND pruning OS ISOs down to a minimal set of packages will both result in broken modular repositories.

    • This could be solved by recreating the RPM’s module streams with exactly the same NSVCA values as the source repository—but practically every step of that will be hacky and require unsupported tooling or several workarounds.

  • The repo manipulation methods (createrepo, repoclosure) aren’t module-aware

Current methods of building/sourcing RPM packages

A SIMP RPM distribution is a self-contained collection of RPM packages:

  • SIMP packages are built by the SIMP team, from the repos under src/ in Puppetfile.pinned.

  • Minimal Base OS packages are filtered from a base OS’s installation media (usually a DVD ISO), down to the files DVD/<os.release.major>-pkglist.txt.

  • External packages are RPMs downloaded based on the data in yum_data/packages.yaml, and come from additional sources (e.g., EPEL, Puppet, base OS extras, various vendors).

  • (Optionally): Custom packages placed manually into either the directory yum_data/packages/ (which locates a yum source like External packages) or yum_data/packages/aux_packages/ (included but not checked).

These packages are distributed by the SIMP ISO. Together, these RPMs MUST self-resolve (enough) to install a basic SIMP system on a network-isolated host.

Current process to build and distribute SIMP ISO release

Here’s a quick summary of the SIMP 6.5.0 build process to illustrate where the problems with modularity will arise:

  1. Build a DVD overlay directory (and tarball) containing the SIMP packages.

  2. ☑ 1️⃣ Download External packages (rake build:yum:sync) into yum_data/packages/

  3. Unpack the base OS installation media into an ISO staging directory.

    1. ☑ 1️⃣ Prune the unpacked ISO RPMs down to the Minimal Base OS packages.

  4. Merge the DVD overlay contents & External packages on top of the files already in the ISO staging directory.

    1. ☑ 2️⃣ Create new yum repositories using createrepo

    2. ☑ 3️⃣ Verify that all ISO staging directory’s RPMs can self-resolve by running repoclosure (rake pkg:repoclosure).

  5. Build a SIMP distribution ISO from the contents of the ISO staging directory

  6. ☑ 1️⃣ Host yum mirrors containing subsets of External package repositories (like EPEL) on the SIMP download service (ex: https://download.simp-project.com/SIMP/yum/releases/6.5.0-1/el/7/x86_64/epel/).

Pain points with modularity + the current process

  • (info)1️⃣: You can’t simply [download the modular RPMs you want/remove the modular RPMS you don’t need/throw a bunch of modular RPMs together] and run createrepo to re-host them. You also need the correct metadata (called modulemd metadata) for all downloaded modular RPMs' streams, and special new commands.

    • AFAICT, this metadata can only be obtained from the source repo.

    • There isn’t a complete “roll-your-own” solution to create modular repositories yet. Most of the tooling is meant to mirror existing repositories. There are community tools (dir2module, repo2module), but they are incomplete, unsupported, and buggy.

  • (info)2️⃣: createrepo_c is needed to create a useable modular repository.
    However, it requires quite a few things before it can work:

    • ⚠4️⃣ The correct modulemd data (see format specs) for modules.yaml from the original repository.

    • ☑ 5️⃣ Some way of generating the modulemd YAML data for each module.

    • ☑ 6️⃣ The ability to add all the modules' modulemd data into a single modules.yaml file for the entire repository.

    • ⚠7️⃣The correct tools to create/merge the repo and the module metadata (createrepo_mod or the *_c commands it runs)

  • (info)3️⃣: yum-utils provides a CLI compatibility layer with the newer DNF sub-commands (including repoclosure), but may require specific arguments (documented further below)

    • dnf repoclosure is sort of module-aware (bz#1547041), and may need extra logic to module enable non-default streams that need to be considered while depsolving.

  • (info)5️⃣6️⃣ To generate the modulemd YAML data for each module and combine it into a single modulemd.yaml file for createrepo_c to consume, we will need to roll either:

    1. build logic to do it in one shot

    2. build logic to glue together a process that combines the buggy community tools from modulemd-tools.

Creating repos with useable modularity streams

⚠8️⃣ We can use tools like dir2module and repo2module[note] to re-package specific packages into slimmer versions of their source modules and then use mergerepo_c (or creatrepo_mod) to collect them into a slimmed-down AppStream/ repo (based on pkglist.txt) or SIMP/ (based on packages.yml). However, there are several issues that make this complicated:

  • RPM packages from repo modules contain a ModularityLabel header that is unique to the module’s name + stream + version + context + architecture (NSVCA). DNF must install these RPMs from modules (with modular metadata)—and will refuse to install them as ursine packages.

    • dir2module and repo2modules require a complete NSVCA string generating module metadata for a directory of RPMs.

    • 5️⃣ The dir2module script provided by the EPEL8 RPM modulemd-tools-0.7-1.el8.noarch does not create a default (or any) profile for the module it creates; it is effectively useless; use repo2module instead (which is still missing the Arch in NSVCA).

  • A repackaged (slim) module’s name and stream and context and architecture must match the values in the source repo’s metadata for the original module.

    • This is required so the packages maintain continuity with the complete upstream repo (e.g., receiving update from the complete AppStream repo, epel-modular, etc)

    • The version number must evaluate to more than the earlier (module versions) and less than the version of later modules in the full source repository. This number (like stream and context) is an arbitrary string set by the build platform, so we have to get it

    • For practical purposes, you need to mirror the repo’s metadata YAML at the same time as you retrieve the packages—it might be updated later, even if the packages you see hosted there are the same

  • The ModularityLabel header is string unique to a module builds' NSVC for a particular platform. The header data in RPMs packaged by RHEL/CentOS build system looks useful because a string it’s in NSVC format, however this data is actually arbitrary and cannot be relied upon to provide accurate NSVC data for the module.

  • The only canonical source for a module’s correct NSVCA/P data is the source repo’s metadata (generally under repodata/{XXXXX}-modules.yaml.gz, and defined by repodata/repomd.xml under <data type="modules">`)

  • 🎉 I’ve tested a repacked “slim” repo alongside a repo with the full module w/identical NSVCA details, and it successfully resolved its metadata/packages with the full module.

    • This should also behave correctly with updated modules, but I haven’t been able to stage that yet.

Testing ISO RPMs' completeness with a repoclosure

Recommendation: Use dnf repoclosure (see below for arguments)

To run a repoclosure against ISO-bound/based repos that are staged on the local filesystem:

dnf repoclosure 
  --disablerepo=\* \
  --repofrompath=base,/mnt/BaseOS \
  --repofrompath=test1,/opt/dnf_reposync_from_iso \
  --arch x86_64 \
  --check base \
  --check tes1

Notes:

  • Make sure there is a --repofrompath= for each local repository directory that should be considered during resolution.

  • Using --disablerepo=\* --repofrompath=, the repoclosure doesn’t require purpose-built *.repo files and doesn’t have to run inside a chroot/container/mock.

  • The --arch x86_64 may be needed to keep the closure focused on the ISO’s target arch.

    • (info) As released, the EL 8.3 ISO’s AppStream/ repo doesn’t close without it.

Impacts to the ISO installation

Recommendation: A minimum, change the createrepo . line in auto.cfg on systems installing modular repositories

This is effectively impossible to test until we have a SIMP ISO with modular repositories.

Impacts to unpack_dvd & self-hosted DNF repositories (for kickstarts, etc)

How should unpack_dvd handle repos that do/may contain modules?

Recommendation: The unpack_dvd tool should assume that all ISO DNF repositories are complete enough to mirror.

(warning) Prerequisites:

  • Any necessary dnf module surgery MUST be completed during the tarball/ISO’s build process (described above)

  • Any “slimmed” dnf modules SHOULD be upgrade-compatible with an unpacked repository than contains the complete modules

If these recommendations are implemented, then a site’s unpack_dvd tool should only need to copy/reposync the files on the ISO.

This has been tested by mounting an ISO as a loopback device and syncing everything (including module metadata) with dnf reposync --download-metadata […] .

  • On a stock EL8 server, dnf reposync needs the dnf-plugins-core package

  • On a stock EL7 server, dnf reposync needs the dnf and dnf-plugins-core packages

How does SELinux support this?

Where do the policies for the packages in various module streams come from?

Notes:

Modularity CLI examples

Simple dnf module commands

View all modules

dnf module list --all

View a module’s available streams

# dnf module list --available nodejs

Waiting for process with pid 79896 to finish.
Last metadata expiration check: 0:00:01 ago on Fri 12 Mar 2021 02:03:02 AM UTC.
CentOS Linux 8 - AppStream
Name                   Stream                 Profiles                                             Summary
nodejs                 10 [d]                 common [d], development, minimal, s2i                Javascript runtime
nodejs                 12                     common [d], development, minimal, s2i                Javascript runtime
nodejs                 14                     common [d], development, minimal, s2i                Javascript runtime

Extra Packages for Enterprise Linux Modular 8 - x86_64
Name                   Stream                 Profiles                                             Summary
nodejs                 13                     default, development, minimal                        Javascript runtime

Hint: [d]efault, [e]nabled, [x]disabled, [i]nstalled

With nicer formatting:

# dnf module list \
  | egrep -v '^(Extra|Name|Hint:|CentOS|Last)' \
  | sed -e '/^$/d' \
  | awk '{printf "%-20s %s\n", $1, $2}' \
  | sort
  
389-directory-server next
389-directory-server stable
389-directory-server testing
389-ds               1.4 
ant                  1.10
avocado              82lts
avocado              latest
cobbler              3
container-tools      1.0
container-tools      2.0
container-tools      rhel8
dwm                  latest
freeradius           3.0
gimp                 2.8
go-toolset           rhel8
httpd                2.4
idm                  DL1
idm                  client
inkscape             0.92.3
javapackages-runtime 201801
jmc                  rhel8
libselinux-python    2.8
libuv                epel8-buildroot
llvm-toolset         rhel8
  

View packages in a module

dnf module repoquery nodejs

It looks dnf module repoquery only reports on the default stream, regardless of the module-spec specified (tested on EL8.3)

View modules/profiles that provide a package

dnf module provides 389-ds-base

This is one of the few (two?) module commands that reports which DNF Repo hosts the module

Note that it also looks for packages across multiple repos and module:streams

Example:

# dnf module provides 389-ds-base
Last metadata expiration check: 1:20:30 ago on Wed Mar 24 18:09:28 2021.
389-ds-base-1.4.3.17-1.module_el8+10764+2b5f8656.x86_64
Module   : 389-directory-server:stable:820201201092549:9edba152:x86_64
Profiles : default legacy minimal
Repo     : epel-modular
Summary  : 389 Directory Server

389-ds-base-1.4.3.8-6.module_el8.3.0+604+ab7bf9cc.x86_64
Module   : 389-ds:1.4:8030020201222185615:618f7055:x86_64
Profiles :
Repo     : appstream
Summary  : 389 Directory Server (base)

389-ds-base-1.4.4.9-1.module_el8+10763+39cf6b48.x86_64
Module   : 389-directory-server:testing:820201201092622:9edba152:x86_64
Profiles : default legacy minimal
Repo     : epel-modular
Summary  : 389 Directory Server

389-ds-base-2.0.1-1.module_el8+10522+e95198da.x86_64
Module   : 389-directory-server:next:820201104083723:9edba152:x86_64
Profiles : default minimal
Repo     : epel-modular
Summary  : 389 Directory Server

View the packages in each profile (for a specific stream)

]# dnf module info --profile  nodejs:12
Last metadata expiration check: 2:59:10 ago on Thu 11 Mar 2021 11:02:32 PM UTC.
Name        : nodejs:12:8030020210304194546:30b713e6:x86_64
common      : nodejs
            : npm
development : nodejs
            : nodejs-devel
            : npm
minimal     : nodejs
s2i         : nodejs
            : nodejs-nodemon
            : npm

Find all modular RPM files that under a directory and print their module headers

This identifies modular RPMs that would need to have their module streams re-created when distributed independently from their source repos:

find "$DIR_WITH_RPMS" -name \*.rpm \
  -exec rpm -qp {} --qf '%{NVRA}   %{ModularityLabel}\n' \; \
  | grep -v '(none)' \
  | tee modular_rpms.txt

The %{ModularityLabel} header is in (module)name:stream:version:context:arch (N:S:V:C:A) format (on RedHat/CentOS/Fedora-built packages), so the result looks like this:

389-ds-base-1.4.3.8-5.module_el8.3.0+473+53682548.x86_64   389-ds:1.4:8030020200831174107:618f7055
389-ds-base-devel-1.4.3.8-5.module_el8.3.0+473+53682548.x86_64   389-ds:1.4:8030020200831174107:618f7055
389-ds-base-legacy-tools-1.4.3.8-5.module_el8.3.0+473+53682548.x86_64   389-ds:1.4:8030020200831174107:618f7055
389-ds-base-libs-1.4.3.8-5.module_el8.3.0+473+53682548.x86_64   389-ds:1.4:8030020200831174107:618f7055
389-ds-base-snmp-1.4.3.8-5.module_el8.3.0+473+53682548.x86_64   389-ds:1.4:8030020200831174107:618f7055
HdrHistogram-2.1.11-2.module_el8.2.0+460+6583c1d0.noarch   jmc:rhel8:8020020200731165725:21dc74c6
HdrHistogram-javadoc-2.1.11-2.module_el8.2.0+460+6583c1d0.noarch   jmc:rhel8:8020020200731165725:21dc74c6
Judy-1.0.5-18.module_el8.1.0+217+4d875839.x86_64   mariadb:10.3:8010020191115015915:cdc1202b
ant-1.10.5-1.module_el8.0.0+47+197dca37.noarch   ant:1.10:8000020190624202340:f7e686af
ant-lib-1.10.5-1.module_el8.0.0+47+197dca37.noarch   ant:1.10:8000020190624202340:f7e686af
aopalliance-1.0-17.module_el8.0.0+39+6a9b6e22.noarch   maven:3.5:8000020190624140656:f7e686af
aopalliance-1.0-20.module_el8.3.0+568+0c23fd64.noarch   maven:3.6:8030020201104064112:a623df05

However, it isn’t possible to re-create specific module/streams based on the RPM’s ModularityLabel headers.

  1. A stream’s full modulemd metadata is only found in the source repo’s *metadata.yaml.gz

  2. The content of ModularityLabel is unique to a build, but its contents cannot be trusted.

By convention, RPMs' ModularityLabel string is in N:S:V:C format, which doesn’t include profile information. Any module streams constructed solely on the RPM header would lose all the original streams' profiles.

Note that the repo2module tool just creates a default profile called everything.

We can’t rely on RPMs' ModularityLabel string to be in N:S:V:C format, either!

“The ModularityLabel can be any string at all. In Fedora, we have a convention to use name:stream:version:context to indicate from which build the RPM originally came from, but this is not to be relied upon. It may change at any time and it also may not be accurately reflective of the module in which it currently resides, due to component-reuse in the Module Build System.”

https://sgallagh.wordpress.com/2019/08/14/sausage-factory-modules-fake-it-till-you-make-it/

Identify all unique modules/streams from a collection of RPM files

find "$DIR_WITH_RPMS" -name \*.rpm \
  -exec rpm -qp {} --qf '%{ModularityLabel}\n' \; \
  | grep -v '^(none)' | sort | uniq -c \
  | sort -nk1,1 \
  | tee unique_rpm_module_streams.txt

Mirror the contents of a DNF repository, preserving all modules and package groups. 

The current state of CentOS 8 createrepo_c + modulemd-tools (EPEL8) allow us to:

(Works from CentOS 8.3 and CentOS 7.8, requires packages dnf and dnf-plugin-core )

An example of this mirroring a mounted CentOS 8.3 ISO’s AppStream repository:

PATH_TO_LOCAL_MIRROR=/path/to/Appstream
PATH_TO_SOURCE_REPO=/mnt/AppStream

dnf reposync \
  --download-metadata --downloadcomps \
  --download-path "$PATH_TO_LOCAL_MIRROR" \
  --repofrompath iso,"$PATH_TO_SOURCE_REPO" \
  --repoid iso

# Useful EL8-only options: --remote-time --norepopath

dnf reposync should probably be the only kind of modular-capable mirroring that on-site tools like unpack_dvd should use.

DNF repoclosure

The ISO build process (really the tar build process) runs repoclosure to make sure the packages on the ISO will be self-contained.

dnf repoclosure --repofrompath iso,"$PWD" --repo appstream --repo baseos

Judging by the bug report at https://bugzilla.redhat.com/show_bug.cgi?id=1547041, dnf repoclosure is not module-aware, in the sense that its resolver does not consider packages in all available modules/streams.

The current behavior only resolves module packages using default or enabled streams & profiles.

Clean DNF install --downloadonly with all deps

Make sure you enable/disable the repos to match what you intend for resolution; --config is an option, too.

DNF_DLONLY_TARGET_PACKAGE=httpd
DNF_DLONLY_INSTALL_ROOT=/root/fake-install-dir
DNF_DLONLY_PACKAGE_DIR=/root/downloadonly

dnf install --downloadonly \
  --setopt=install_weak_deps=False \
  --installroot="$DNF_DLONLY_INSTALL_ROOT" \
  --downloaddir="$DNF_DLONLY_PACKAGE_DIR" \
  --disablerepo=\* \
  --enablerepo=baseos \
  --enablerepo=appstream \
  --releasever=8 \
  "$DNF_DLONLY_TARGET_PACKAGE"

Notes:

  • An an --enablerepo= for each repo to consider during resolution.

  • Pointing to an empty --installroot= will cause dnf install --downloadonly to download EVERY dependency, including the packages for the baseos.

  • In this case, --setopt=install_weak_deps=False may be useful to ignore weak RPM dependencies and cut down on the download size.

Create initial repo with ursine modules

mkdir -p $NEW_REPO_DIR/Packages/ursine
cp "${URSINE_PACKAGE_FILES[@]}" "$NEW_REPO_DIR/Packages/ursine/"
cd "$NEW_REPO_DIR"
createrepo_c .
  • Create a modular repo from packages that already have a common module header
    (warning)WARNING The approach of taking N:S:V:C:A from the RPM headers below is a.) incomplete and b.) cannot be relied upon to be accurate or present—the ModularityLabel header can contain any String.

    (warning)DO NOT PRODUCTIZE Use another means to obtain N:V:S:C:A data; preferably from the repo itself (the data is sourced from the source repository’s {XXXXX}-modules.yaml.gz file)

    # Get the ModularityLabel from the RPMs
    ##########################################################
    #### UPDATE: DO NOT USE OR PRODUCTIZE THIS TECHNIQUE #####
    ##########################################################
    
    # Notes: 
    #  - All RPMs in the module must have a SINGLE and IDENTICAL ModularityLabel
    #  - The only thing required of this String is that it is unique to RPMs 
    #    from other modules (and different versions/contexts of this module)
    find "$DIR_WITH_RPMS" -name \*.rpm  \
      -exec rpm -qp {} --qf '%{ModularityLabel}\n' \;  \
      | sort -u
    
    ### WARNING: the ModularityLabel headers in RPMs build by EL and EPEL 
    ####         are (currently) in N:S:V:C format by convention, but in 
    #####        reality this string is arbitrary and cannot be relied upon
    #####        to reflect the actual source module's metadata.
    #####        The actual NVSCA/P data can *ONLY* be obtained from the 
    #####        original repo's metadata
    MODULE_HEADER=nodejs:10:8020020200707141642:6a468ee4
    
    

Documentation

Modularity direction

In early 2020, modularity development moved from Fedora’s Modularity WG to RedHat’s internal DNF team. Fedora development and governance was very open and public, which made it relatively easy to hunt down clarifying information about otherwise obscure details in pagure or the WG’s meeting logs.

Since RedHat took over, it has become very difficult to find up-to-date documentation or discussions, even (especially?) in BZ.

  • Fedora Council and the future of Modularity (March 2020 blog post)

    • > “ Since then, responsibility for Modularity development in Red Hat moved to a new team. This presents a good opportunity to reset opinions and start anew. As the new team gets their arms around Modularity, you can expect an updated Objective proposal that will improve Modularity for Fedora. “

  • RHEL 9 and modularity (18 June 2020, Fedora devel@ mailing list)

    • Discussion with official RedHat rep, after taking modularity from Fedora and moving its development to an internal DNF team.

    • There’s also a side-discussion in the middle about the “inevitability” of moving the modular “namespacing” (N:S?) into RPM’s headers/tags (like ModularityLabel), where several of Fedora’s former modular WG members chime in with some educational

More esoteric things that may come in handy in the future:

  • https://github.com/fedora-modularity/fus — 'This tool attempts to produce a viable "depsolved" collection of packages.

    Unlike earlier tools of this type, it understands the concept of modules and module streams and can incorporate them into the dependency solving algorithm.'

    • See NOTES in README on limitations

  • https://github.com/fedora-modularity/depchase — “[a] simple script to lookup runtime (and/or buildtime) requirements of package(s).”

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