A large number of issues reported against Podman are often found to already be fixed
in more current versions of the project. Before reporting an issue, please verify the
version you are running with podman version
and compare it to the latest release
documented on the top of Podman's README.md.
If they differ, please update your version of PODMAN to the latest possible and retry your command before reporting the issue.
$ podman run -v ~/mycontent:/content fedora touch /content/file
touch: cannot touch '/content/file': Permission denied
This is sometimes caused by SELinux, and sometimes by user namespaces.
Labeling systems like SELinux require that proper labels are placed on volume content mounted into a container. Without a label, the security system might prevent the processes running inside the container from using the content. By default, Podman does not change the labels set by the OS.
To change a label in the container context, you can add either of two suffixes :z or :Z to the volume mount. These suffixes tell Podman to relabel file objects on the shared volumes. The z option tells Podman that two containers share the volume content. As a result, Podman labels the content with a shared content label. Shared volume labels allow all containers to read/write content. The Z option tells Podman to label the content with a private unshared label. Only the current container can use a private volume.
$ podman run -v ~/mycontent:/content:Z fedora touch /content/file
Make sure the content is private for the container. Do not relabel system directories and content.
Relabeling system content might cause other confined services on your machine to fail. For these
types of containers we recommend having SELinux separation disabled. The option --security-opt label=disable
will disable SELinux separation for the container.
$ podman run --security-opt label=disable -v ~:/home/user fedora touch /home/user/file
In cases where the container image runs as a specific, non-root user, though, the
solution is to fix the user namespace. This would include container images such as
the Jupyter Notebook image (which runs as "jovyan") and the Postgres image (which runs
as "postgres"). In either case, use the --userns
switch to map user namespaces,
most of the time by using the keep-id option.
$ podman run -v "$PWD":/home/jovyan/work --userns=keep-id jupyter/scipy-notebook
When doing a podman pull
or podman build
command and a "common" image cannot be pulled,
it is likely that the /etc/containers/registries.conf
file is either not installed or possibly
misconfigured.
$ sudo podman build -f Dockerfile
STEP 1: FROM alpine
error building: error creating build container: no such image "alpine" in registry: image not known
or
$ sudo podman pull fedora
error pulling image "fedora": unable to pull fedora: error getting default registries to try: Near line 9 (last key parsed ''): Bare keys cannot contain ':'.
- Verify that the
/etc/containers/registries.conf
file exists. If not, verify that the containers-common package is installed. - Verify that the entries in the
unqualified-search-registries
list of the/etc/containers/registries.conf
file are valid and reachable.- i.e.
unqualified-search-registries = ["registry.fedoraproject.org", "quay.io", "registry.access.redhat.com"]
- i.e.
When doing a Podman command such as build
, commit
, pull
, or push
to a registry,
TLS verification is turned on by default. If encryption is not used with
those commands, this error can occur.
$ sudo podman push alpine docker://localhost:5000/myalpine:latest
Getting image source signatures
Get https://localhost:5000/v2/: http: server gave HTTP response to HTTPS client
By default TLS verification is turned on when communicating to registries from
Podman. If the registry does not require encryption the Podman commands
such as build
, commit
, pull
and push
will fail unless TLS verification is turned
off using the --tls-verify
option. NOTE: It is not at all recommended to
communicate with a registry and not use TLS verification.
- Turn off TLS verification by passing false to the tls-verify option.
- I.e.
podman push --tls-verify=false alpine docker://localhost:5000/myalpine:latest
When using the ping command from a non-root container, the command may fail because of a lack of privileges.
$ podman run --rm fedora ping -W10 -c1 redhat.com
PING redhat.com (209.132.183.105): 56 data bytes
--- redhat.com ping statistics ---
1 packets transmitted, 0 packets received, 100% packet loss
It is most likely necessary to enable unprivileged pings on the host.
Be sure the UID of the user is part of the range in the
/proc/sys/net/ipv4/ping_group_range
file.
To change its value you can use something like:
# sysctl -w "net.ipv4.ping_group_range=0 2000000"
To make the change persistent, you'll need to add a file in
/etc/sysctl.d
that contains net.ipv4.ping_group_range=0 $MAX_UID
.
When the Dockerfile contains a command like RUN useradd -u 99999000 -g users newuser
the build can hang.
If you are using a useradd command within a Dockerfile with a large UID/GID, it will create a large sparse file /var/log/lastlog
. This can cause the build to hang forever. Go language does not support sparse files correctly, which can lead to some huge files being created in your container image.
If the entry in the Dockerfile looked like: RUN useradd -u 99999000 -g users newuser then add the --no-log-init
parameter to change it to: RUN useradd --no-log-init -u 99999000 -g users newuser
. This option tells useradd to stop creating the lastlog file.
When rootless Podman attempts to execute a container on a non exec home directory a permission error will be raised.
If you are running Podman or Buildah on a home directory that is mounted noexec, then they will fail with a message like:
$ podman run centos:7
standard_init_linux.go:203: exec user process caused "permission denied"
Since the administrator of the system set up your home directory to be noexec, you will not be allowed to execute containers from storage in your home directory. It is possible to work around this by manually specifying a container storage path that is not on a noexec mount. Simply copy the file /etc/containers/storage.conf to ~/.config/containers/ (creating the directory if necessary). Specify a graphroot directory which is not on a noexec mount point and to which you have read/write privileges. You will need to modify other fields to writable directories as well.
For example
$ cat ~/.config/containers/storage.conf
[storage]
driver = "overlay"
runroot = "/run/user/1000"
graphroot = "/execdir/myuser/storage"
[storage.options]
mount_program = "/bin/fuse-overlayfs"
When running systemd as PID 1 inside of a container on an SELinux separated machine, it needs to write to the cgroup file system.
Systemd gets permission denied when attempting to write to the cgroup file system, and AVC messages start to show up in the audit.log file or journal on the system.
Newer versions of Podman (2.0 or greater) support running init based containers with a different SELinux labels, which allow the container process access to the cgroup file system. This feature requires container-selinux-2.132 or newer versions.
Prior to Podman 2.0, the SELinux boolean container_manage_cgroup
allows
container processes to write to the cgroup file system. Turn on this boolean,
on SELinux separated systems, to allow systemd to run properly in the container.
Only do this on systems running older versions of Podman.
# setsebool -P container_manage_cgroup true
Rootless Podman requires the newuidmap and newgidmap programs to be installed.
If you are running Podman or Buildah as a rootless user, you get an error complaining about a missing newuidmap executable.
$ podman run -ti fedora sh
command required for rootless mode with multiple IDs: exec: "newuidmap": executable file not found in $PATH
Install a version of shadow-utils that includes these executables. Note that for RHEL and CentOS 7, at least the 7.7 release must be installed for support to be available.
Rootless Podman requires the user running it to have a range of UIDs listed in /etc/subuid and /etc/subgid.
A user, either via --user or through the default configured for the image, is not mapped inside the namespace.
$ podman run --rm -ti --user 1000000 alpine echo hi
Error: container create failed: container_linux.go:344: starting container process caused "setup user: invalid argument"
Update the /etc/subuid and /etc/subgid with fields for users that look like:
$ cat /etc/subuid
johndoe:100000:65536
test:165536:65536
The format of this file is USERNAME:UID:RANGE
- username as listed in
/etc/passwd
orgetpwent
. - The initial uid allocated for the user.
- The size of the range of UIDs allocated for the user.
This means johndoe is allocated UIDs 100000-165535 as well as his standard UID in the
/etc/passwd
file.
You should ensure that each user has a unique range of UIDs, because overlapping UIDs, would potentially allow one user to attack another user. In addition, make sure that the range of UIDs you allocate can cover all UIDs that the container requires. For example, if the container has a user with UID 10000, ensure you have at least 10001 subuids, and if the container needs to be run as a user with UID 1000000, ensure you have at least 1000001 subuids.
You could also use the usermod
program to assign UIDs to a user.
If you update either the /etc/subuid
or /etc/subgid
file, you need to
stop all running containers and kill the pause process. This is done
automatically by the system migrate
command, which can also be used
to stop all the containers and kill the pause process.
# usermod --add-subuids 200000-201000 --add-subgids 200000-201000 johndoe
# grep johndoe /etc/subuid /etc/subgid
/etc/subuid:johndoe:200000:1001
/etc/subgid:johndoe:200000:1001
When I change the graphroot storage location in storage.conf, the next time I run Podman, I get an error like:
# podman run -p 5000:5000 -it centos bash
bash: error while loading shared libraries: /lib64/libc.so.6: cannot apply additional memory protection after relocation: Permission denied
For example, the admin sets up a spare disk to be mounted at /src/containers
,
and points storage.conf at this directory.
SELinux blocks containers from using arbitrary locations for overlay storage.
These directories need to be labeled with the same labels as if the content was
under /var/lib/containers/storage
.
Tell SELinux about the new containers storage by setting up an equivalence record.
This tells SELinux to label content under the new path, as if it was stored
under /var/lib/containers/storage
.
# semanage fcontext -a -e /var/lib/containers /srv/containers
# restorecon -R -v /srv/containers
The semanage command above tells SELinux to setup the default labeling of
/srv/containers
to match /var/lib/containers
. The restorecon
command
tells SELinux to apply the labels to the actual content.
Now all new content created in these directories will automatically be created with the correct label.
Pulling an anonymous image that doesn't require authentication can result in an
invalid username/password
error.
If you pull an anonymous image, one that should not require credentials, you can receive
an invalid username/password
error if you have credentials established in the
authentication file for the target container registry that are no longer valid.
$ podman run -it --rm docker://docker.io/library/alpine:latest ls
Trying to pull docker://docker.io/library/alpine:latest...ERRO[0000] Error pulling image ref //alpine:latest: Error determining manifest MIME type for docker://alpine:latest: unable to retrieve auth token: invalid username/password
Failed
Error: unable to pull docker://docker.io/library/alpine:latest: unable to pull image: Error determining manifest MIME type for docker://alpine:latest: unable to retrieve auth token: invalid username/password
This can happen if the authentication file is modified 'by hand' or if the credentials are established locally and then the password is updated later in the container registry.
Depending upon which container tool was used to establish the credentials, use podman logout
or docker logout
to remove the credentials from the authentication file.
Running Podman in a container and forwarding some, but not all, of the required host directories can cause inconsistent container behavior.
After creating a container with Podman's storage directories mounted in from the host and running Podman inside a container, all containers show their state as "configured" or "created", even if they were running or stopped.
When running Podman inside a container, it is recommended to mount at a minimum /var/lib/containers/storage/
as a volume.
Typically, you will not mount in the host version of the directory, but if you wish to share containers with the host, you can do so.
If you do mount in the host's /var/lib/containers/storage
, however, you must also mount in the host's /run/libpod
and /run/containers/storage
directories.
Not doing this will cause Podman in the container to detect that temporary files have been cleared, leading it to assume a system restart has taken place.
This can cause Podman to reset container states and lose track of running containers.
For running containers on the host from inside a container, we also recommend the Podman remote client, which only requires a single socket to be mounted into the container.
NFS enforces file creation on different UIDs on the server side and does not understand user namespace, which rootless Podman requires. When a container root process like YUM attempts to create a file owned by a different UID, NFS Server denies the creation. NFS is also a problem for the file locks when the storage is on it. Other distributed file systems (for example: Lustre, Spectrum Scale, the General Parallel File System (GPFS)) are also not supported when running in rootless mode as these file systems do not understand user namespace.
$ podman build .
ERRO[0014] Error while applying layer: ApplyLayer exit status 1 stdout: stderr: open /root/.bash_logout: permission denied
error creating build container: Error committing the finished image: error adding layer with blob "sha256:a02a4930cb5d36f3290eb84f4bfa30668ef2e9fe3a1fb73ec015fc58b9958b17": ApplyLayer exit status 1 stdout: stderr: open /root/.bash_logout: permission denied
Choose one of the following:
- Setup containers/storage in a different directory, not on an NFS share.
- Create a directory on a local file system.
- Edit
~/.config/containers/containers.conf
and point thevolume_path
option to that local directory. (Copy/usr/share/containers/containers.conf
if~/.config/containers/containers.conf
does not exist)
- Otherwise just run Podman as root, via
sudo podman
The Overlay file system (OverlayFS) requires the ability to call the mknod
command when creating whiteout files
when extracting an image. However, a rootless user does not have the privileges to use mknod
in this capacity.
$ podman build --storage-driver overlay .
STEP 1: FROM docker.io/ubuntu:xenial
Getting image source signatures
Copying blob edf72af6d627 done
Copying blob 3e4f86211d23 done
Copying blob 8d3eac894db4 done
Copying blob f7277927d38a done
Copying config 5e13f8dd4c done
Writing manifest to image destination
Storing signatures
Error: error creating build container: Error committing the finished image: error adding layer with blob "sha256:8d3eac894db4dc4154377ad28643dfe6625ff0e54bcfa63e0d04921f1a8ef7f8": Error processing tar file(exit status 1): operation not permitted
$ podman build .
ERRO[0014] Error while applying layer: ApplyLayer exit status 1 stdout: stderr: open /root/.bash_logout: permission denied
error creating build container: Error committing the finished image: error adding layer with blob "sha256:a02a4930cb5d36f3290eb84f4bfa30668ef2e9fe3a1fb73ec015fc58b9958b17": ApplyLayer exit status 1 stdout: stderr: open /root/.bash_logout: permission denied
Choose one of the following:
- Complete the build operation as a privileged user.
- Install and configure fuse-overlayfs.
- Install the fuse-overlayfs package for your Linux Distribution.
- Add
mount_program = "/usr/bin/fuse-overlayfs"
under[storage.options]
in your~/.config/containers/storage.conf
file.
The systemd version shipped in RHEL 7 and CentOS 7 doesn't have support for cgroup v2. Support for cgroup v2 requires version 230 of systemd or newer, which was never shipped or supported on RHEL 7 or CentOS 7.
# podman run --name test -d registry.access.redhat.com/rhel7-init:latest && sleep 10 && podman exec test systemctl status
c8567461948439bce72fad3076a91ececfb7b14d469bfa5fbc32c6403185beff
Failed to get D-Bus connection: Operation not permitted
Error: non zero exit code: 1: OCI runtime error
You'll need to either:
- configure the host to use cgroup v1. On Fedora you can do:
# dnf install -y grubby
# grubby --update-kernel=ALL --args=”systemd.unified_cgroup_hierarchy=0"
# reboot
- update the image to use an updated version of systemd.
You need to set lingering mode through loginctl to prevent user processes to be killed once the user session completed.
Once the user logs out all the containers exit.
You'll need to either:
# loginctl enable-linger $UID
The Kernel Lockdown patches deny eBPF programs when Secure Boot is enabled in the BIOS. Matthew Garrett's post describes the relationship between Lockdown and Secure Boot and Jan-Philip Gehrcke's connects this with eBPF. RH bug 1768125 contains some additional details.
Attempts to run podman result in
Error: bpf create : Operation not permitted: OCI runtime permission denied error
One workaround is to disable Secure Boot in your BIOS.
Unable to pull images
$ podman unshare cat /proc/self/uid_map
0 1000 1
$ podman system migrate
Original command now returns
$ podman unshare cat /proc/self/uid_map
0 1000 1
1 100000 65536
Reference subuid and subgid man pages for more detail.
As a non-root user you have group access rights to a device or files that you
want to pass into a rootless container with --device=...
or --volume=...
Any access inside the container is rejected with "Permission denied".
The runtime uses setgroups(2)
hence the process loses all additional groups
the non-root user has. Use the --group-add keep-groups
flag to pass the
user's supplementary group access into the container. Currently only available
with the crun
OCI runtime.
When running a container with a command like podman run --detach httpd
as
a rootless user, the container is closed upon logout and is not kept running.
When logging out of a rootless user session, all containers that were started in detached mode are stopped and are not kept running. As the root user, these same containers would survive the logout and continue running.
When systemd notes that a session that started a Podman container has exited,
it will also stop any containers that has been associated with it. To avoid
this, use the following command before logging out: loginctl enable-linger
.
To later revert the linger functionality, use loginctl disable-linger
.
LOGINCTL(1), SYSTEMD(1)
Podman defaults to ctrl-p,ctrl-q
to detach from a running containers. The
bash and zsh shells default to ctrl-p
for the displaying of the previous
command. This causes issues when running a shell inside of a container.
With the default detach key combo ctrl-p,ctrl-q, shell history navigation (tested in bash and zsh) using ctrl-p to access the previous command will not display this previous command, or anything else. Conmon is waiting for an additional character to see if the user wants to detach from the container. Adding additional characters to the command will cause it to be displayed along with the additional character. If the user types ctrl-p a second time the shell display the 2nd to last command.
The solution to this is to change the default detach_keys. For example in order
to change the defaults to ctrl-q,ctrl-q
use the --detach-keys
option.
$ podman run -ti --detach-keys ctrl-q,ctrl-q fedora sh
To make this change the default for all containers, users can modify the containers.conf file. This can be done simply in your home directory, but adding the following lines to users containers.conf
$ cat >> ~/.config/containers/containers.conf << _eof
[engine]
detach_keys="ctrl-q,ctrl-q"
_eof
In order to effect root running containers and all users, modify the system
wide defaults in /etc/containers/containers.conf
.
A container with ports that have been published with the --publish
or -p
option
can not be run within a pod.
$ podman pod create --name srcview -p 127.0.0.1:3434:3434 -p 127.0.0.1:7080:7080 -p 127.0.0.1:3370:3370 4b2f4611fa2cbd60b3899b936368c2b3f4f0f68bc8e6593416e0ab8ecb0a3f1d
$ podman run --pod srcview --name src-expose -p 3434:3434 -v "${PWD}:/var/opt/localrepo":Z,ro sourcegraph/src-expose:latest serve /var/opt/localrepo
Error: cannot set port bindings on an existing container network namespace
This is a known limitation. If a container will be run within a pod, it is not necessary to publish the port for the containers in the pod. The port must only be published by the pod itself. Pod network stacks act like the network stack on the host - you have a variety of containers in the pod, and programs in the container, all sharing a single interface and IP address, and associated ports. If one container binds to a port, no other container can use that port within the pod while it is in use. Containers in the pod can also communicate over localhost by having one container bind to localhost in the pod, and another connect to that port.
In the example from the symptom section, dropping the -p 3434:3434
would allow the
podman run
command to complete, and the container as part of the pod would still have
access to that port. For example:
$ podman run --pod srcview --name src-expose -v "${PWD}:/var/opt/localrepo":Z,ro sourcegraph/src-expose:latest serve /var/opt/localrepo
Some container images require that the fuse kernel module is loaded in the kernel before they will run with the fuse filesystem in play.
When trying to run the container images found at quay.io/podman, quay.io/containers registry.access.redhat.com/ubi8 or other locations, an error will sometimes be returned:
ERRO error unmounting /var/lib/containers/storage/overlay/30c058cdadc888177361dd14a7ed7edab441c58525b341df321f07bc11440e68/merged: invalid argument
error mounting container "1ae176ca72b3da7c70af31db7434bcf6f94b07dbc0328bc7e4e8fc9579d0dc2e": error mounting build container "1ae176ca72b3da7c70af31db7434bcf6f94b07dbc0328bc7e4e8fc9579d0dc2e": error creating overlay mount to /var/lib/containers/storage/overlay/30c058cdadc888177361dd14a7ed7edab441c58525b341df321f07bc11440e68/merged: using mount program /usr/bin/fuse-overlayfs: fuse: device not found, try 'modprobe fuse' first
fuse-overlayfs: cannot mount: No such device
: exit status 1
ERRO exit status 1
If you encounter a fuse: device not found
error when running the container image, it is likely that
the fuse kernel module has not been loaded on your host system. Use the command modprobe fuse
to load the
module and then run the container image afterwards. To enable this automatically at boot time, you can add a configuration
file to /etc/modules.load.d
. See man modules-load.d
for more details.
An error such as "OCI runtime error" on a read-only filesystem or the error "{image} is not an absolute path or is a symlink" are often times indicators for this issue. For more details, review this issue.
Rootless Podman requires certain files to exist in a file system in order to run. Podman will create /etc/resolv.conf, /etc/hosts and other file descriptors on the rootfs in order to mount volumes on them.
Run the container once in read/write mode, Podman will generate all of the FDs on the rootfs, and from that point forward you can run with a read-only rootfs.
$ podman run --rm --rootfs /path/to/rootfs true
The command above will create all the missing directories needed to run the container.
After that, it can be used in read only mode, by multiple containers at the same time:
$ podman run --read-only --rootfs /path/to/rootfs ....
Another option is to use an Overlay Rootfs Mount:
$ podman run --rootfs /path/to/rootfs:O ....
Modifications to the mount point are destroyed when the container finishes executing, similar to a tmpfs mount point being unmounted.
On some systemd-based systems, non-root users do not have CPU limit delegation permissions. This causes setting CPU limits to fail.
Running a container with a CPU limit options such as --cpus
, --cpu-period
,
or --cpu-quota
will fail with an error similar to the following:
Error: opening file `cpu.max` for writing: Permission denied: OCI runtime permission denied error
This means that CPU limit delegation is not enabled for the current user.
You can verify whether CPU limit delegation is enabled by running the following command:
$ cat "/sys/fs/cgroup/user.slice/user-$(id -u).slice/user@$(id -u).service/cgroup.controllers"
Example output might be:
memory pids
In the above example, cpu
is not listed, which means the current user does
not have permission to set CPU limits.
If you want to enable CPU limit delegation for all users, you can create the
file /etc/systemd/system/[email protected]/delegate.conf
with the contents:
[Service]
Delegate=memory pids cpu io
After logging out and logging back in, you should have permission to set CPU limits.
This can happen when running a container from an image for another architecture than the one you are running on.
For example, if a remote repository only has, and thus send you, a linux/arm64
OS/ARCH but you run on linux/amd64
(as happened in openMF/community-app#3323 due to timbru31/docker-ruby-node#564).
27) Error: failed to create sshClient: Connection to bastion host (ssh://user@host:22/run/user/.../podman/podman.sock) failed.: ssh: handshake failed: ssh: unable to authenticate, attempted methods [none publickey], no supported methods remain
In some situations where the client is not on the same machine as where the podman daemon is running the client key could be using a cipher not supported by the host. This indicates an issue with one's SSH config. Until remedied using podman over ssh with a pre-shared key will be impossible.
The accepted ciphers per /etc/crypto-policies/back-ends/openssh.config
are not one that was used to create the public/private key pair that was transferred over to the host for ssh authentication.
You can confirm this is the case by attempting to connect to the host via podman-remote info
from the client and simultaneously on the host running journalctl -f
and watching for the error userauth_pubkey: key type ssh-rsa not in PubkeyAcceptedAlgorithms [preauth]
.
Create a new key using a supported algorithm e.g. ecdsa:
$ ssh-keygen -t ecdsa -f ~/.ssh/podman
Then copy the new id over:
$ ssh-copy-id -i ~/.ssh/podman.pub user@host
And then re-add the connection (removing the old one if necessary):
$ podman-remote system connection add myuser --identity ~/.ssh/podman ssh://user@host/run/user/1000/podman/podman.sock
And now this should work:
$ podman-remote info
A failure is encountered when trying to use networking on a rootless container in Podman v2.2.1 through v3.0.1 on RHEL. This error does not occur on other Linux distributions.
A rootless container is created using a CNI network, but the podman run
command
returns an error that an image must be built.
In order to use a CNI network in a rootless container on RHEL, an Infra container image for CNI-in-slirp4netns must be created. The instructions for building the Infra container image can be found for v2.2.1 here, and for v3.0.1 here.
Container network can't be reached after firewall-cmd --reload
and systemctl restart firewalld
Running podman network reload
will fix it but it has to be done manually.
The firewall rules created by podman are lost when the firewall is reloaded.
@ranjithrajaram has created a systemd-hook to fix this issue
- For "firewall-cmd --reload", create a systemd unit file with the following
[Unit]
Description=firewalld reload hook - run a hook script on firewalld reload
Wants=dbus.service
After=dbus.service
[Service]
Type=simple
ExecStart=/bin/bash -c '/bin/busctl monitor --system --match "interface=org.fedoraproject.FirewallD1,member=Reloaded" --match "interface=org.fedoraproject.FirewallD1,member=PropertiesChanged" | while read -r line ; do podman network reload --all ; done'
[Install]
WantedBy=default.target
- For "systemctl restart firewalld", create a systemd unit file with the following
[Unit]
Description=podman network reload
Wants=firewalld.service
After=firewalld.service
PartOf=firewalld.service
[Service]
Type=simple
RemainAfterExit=yes
ExecStart=/usr/bin/podman network reload --all
[Install]
WantedBy=default.target
However, If you use busctl monitor then you can't get machine-readable output on RHEL 8.
Since it doesn't have busctl -j
as mentioned here by @yrro.
For RHEL 8, you can use the following one-liner bash script.
[Unit]
Description=Redo podman NAT rules after firewalld starts or reloads
Wants=dbus.service
After=dbus.service
Requires=firewalld.service
[Service]
Type=simple
ExecStart=/bin/bash -c "dbus-monitor --profile --system 'type=signal,sender=org.freedesktop.DBus,path=/org/freedesktop/DBus,interface=org.freedesktop.DBus,member=NameAcquired,arg0=org.fedoraproject.FirewallD1' 'type=signal,path=/org/fedoraproject/FirewallD1,interface=org.fedoraproject.FirewallD1,member=Reloaded' | sed -u '/^#/d' | while read -r type timestamp serial sender destination path interface member _junk; do if [[ $type = '#'* ]]; then continue; elif [[ $interface = org.freedesktop.DBus && $member = NameAcquired ]]; then echo 'firewalld started'; podman network reload --all; elif [[ $interface = org.fedoraproject.FirewallD1 && $member = Reloaded ]]; then echo 'firewalld reloaded'; podman network reload --all; fi; done"
Restart=Always
[Install]
WantedBy=default.target
busctl-monitor
is almost usable in RHEL 8, except that it always outputs two bogus events when it starts up,
one of which is (in its only machine-readable format) indistinguishable from the NameOwnerChanged
that you get when firewalld starts up.
This means you would get an extra podman network reload --all
when this unit starts.
Apart from this, you can use the following systemd service with the python3 code.
[Unit]
Description=Redo podman NAT rules after firewalld starts or reloads
Wants=dbus.service
Requires=firewalld.service
After=dbus.service
[Service]
Type=simple
ExecStart=/usr/bin/python /path/to/python/code/podman-redo-nat.py
Restart=always
[Install]
WantedBy=default.target
The code reloads podman network twice when you use systemctl restart firewalld
.
import dbus
from gi.repository import GLib
from dbus.mainloop.glib import DBusGMainLoop
import subprocess
import sys
# I'm a bit confused on the return values in the code
# Not sure if they are needed.
def reload_podman_network():
try:
subprocess.run(["podman","network","reload","--all"],timeout=90)
# I'm not sure about this part
sys.stdout.write("podman network reload done\n")
sys.stdout.flush()
except subprocess.TimeoutExpired as t:
sys.stderr.write(f"Podman reload failed due to Timeout {t}")
except subprocess.CalledProcessError as e:
sys.stderr.write(f"Podman reload failed due to {e}")
except Exception as e:
sys.stderr.write(f"Podman reload failed with an Unhandled Exception {e}")
return False
def signal_handler(*args, **kwargs):
if kwargs.get('member') == "Reloaded":
reload_podman_network()
elif kwargs.get('member') == "NameOwnerChanged":
reload_podman_network()
else:
return None
return None
def signal_listener():
try:
DBusGMainLoop(set_as_default=True)# Define the loop.
loop = GLib.MainLoop()
system_bus = dbus.SystemBus()
# Listens to systemctl restart firewalld with a filter added, will cause podman network to be reloaded twice
system_bus.add_signal_receiver(signal_handler,dbus_interface='org.freedesktop.DBus',arg0='org.fedoraproject.FirewallD1',member_keyword='member')
# Listens to firewall-cmd --reload
system_bus.add_signal_receiver(signal_handler,dbus_interface='org.fedoraproject.FirewallD1',signal_name='Reloaded',member_keyword='member')
loop.run()
except KeyboardInterrupt:
loop.quit()
sys.exit(0)
except Exception as e:
loop.quit()
sys.stderr.write(f"Error occurred {e}")
sys.exit(1)
if __name__ == "__main__":
signal_listener()
30) Podman run fails with ERRO[0000] XDG_RUNTIME_DIR directory "/run/user/0" is not owned by the current user
or Error: error creating tmpdir: mkdir /run/user/1000: permission denied
.
A failure is encountered when performing podman run
with a warning XDG_RUNTIME_DIR is pointing to a path which is not writable. Most likely podman will fail.
A rootless container is being invoked with cgroup configuration as cgroupv2
for user with missing or invalid systemd session.
Example cases
# su user1 -c 'podman images'
ERRO[0000] XDG_RUNTIME_DIR directory "/run/user/0" is not owned by the current user
# su - user1 -c 'podman images'
Error: error creating tmpdir: mkdir /run/user/1000: permission denied
Podman expects a valid login session for the rootless+cgroupv2
use-case. Podman execution is expected to fail if the login session is not present. In most cases, podman will figure out a solution on its own but if XDG_RUNTIME_DIR
is pointing to a path that is not writable execution will most likely fail. Typical scenarios of such cases are seen when users are trying to use Podman with su - <user> -c '<podman-command>'
, or sudo -l
and badly configured systemd session.
Alternatives:
-
Execute Podman via systemd-run that will first start a systemd login session:
$ sudo systemd-run --machine=username@ --quiet --user --collect --pipe --wait podman run --rm docker.io/library/alpine echo hello
-
Start an interactive shell in a systemd login session with the command
machinectl shell <username>@
and then run Podman$ sudo -i # machinectl shell username@ Connected to the local host. Press ^] three times within 1s to exit session. $ podman run --rm docker.io/library/alpine echo hello
-
Start a new systemd login session by logging in with
ssh
i.e.ssh <username>@localhost
and then run Podman. -
Before invoking Podman command create a valid login session for your rootless user using
loginctl enable-linger <username>
After deleting a VM on macOS, the initialization of subsequent VMs fails.
After deleting a client VM on macOS via podman machine stop
&& podman machine rm
, attempting to podman machine init
a new client VM leads to an error with the 127.0.0.1:7777 port already bound.
You will need to remove the hanging gv-proxy process bound to the port in question. For example, if the port mentioned in the error message is 127.0.0.1:7777, you can use the command kill -9 $(lsof -i:7777)
in order to identify and remove the hanging process which prevents you from starting a new VM on that default port.
The sshd process running inside the container fails with the error "Error writing /proc/self/loginuid".
If the /proc/self/loginuid
file is already initialized then the
CAP_AUDIT_CONTROL
capability is required to override it.
This happens when running Podman from a user session since the
/proc/self/loginuid
file is already initialized. The solution is to
run Podman from a system service, either using the Podman service, and
then using podman -remote to start the container or simply by running
something like systemd-run podman run ...
. In this case the
container will only need CAP_AUDIT_WRITE
.
After running a container with rootless Podman, the non-root user sees a numerical UID and GID instead of a username and groupname.
When listing file permissions with ls -l
on the host in a directory that was passed as --volume /some/dir
to podman run
,
the UID and GID are displayed rather than the corresponding username and groupname. The UID and GID numbers displayed are
from the user's subordinate UID and GID ranges on the host system.
An example
$ mkdir dir1
$ chmod 777 dir1
$ podman run --rm -v ./dir1:/dir1:Z \
--user 2003:2003 \
docker.io/library/ubuntu bash -c "touch /dir1/a; chmod 600 /dir1/a"
$ ls -l dir1/a
-rw-------. 1 102002 102002 0 Jan 19 19:35 dir1/a
$ less dir1/a
less: dir1/a: Permission denied
If you want to read, chown, or remove such a file, enter a user
namespace. Instead of running commands such as less dir1/a
or rm dir1/a
, you
need to prepend the command-line with podman unshare
, i.e.,
podman unshare less dir1/a
or podman unshare rm dir1/a
. To change the ownership
of the file dir1/a
to your regular user's UID and GID, run podman unshare chown 0:0 dir1/a
.
A file having the ownership 0:0
in the user namespace is owned by the regular
user on the host. To use Bash features, such as variable expansion and
globbing, you need to wrap the command with bash -c
, e.g.
podman unshare bash -c 'ls $HOME/dir1/a*'
.
Would it have been possible to run Podman in another way so that your regular user would have become the owner of the file? Yes, you can use the options --uidmap and --gidmap to change how UIDs and GIDs are mapped between the container and the host. Let's try it out.
In the example above ls -l
shows the UID 102002 and GID 102002. Set shell variables
$ uid_from_ls=102002
$ gid_from_ls=102002
Set shell variables to the lowest subordinate UID and GID
$ lowest_subuid=$(podman info --format "{{ (index .Host.IDMappings.UIDMap 1).HostID }}")
$ lowest_subgid=$(podman info --format "{{ (index .Host.IDMappings.GIDMap 1).HostID }}")
Compute the UID and GID inside the container that map to the owner of the created file on the host.
$ uid=$(( $uid_from_ls - $lowest_subuid + 1))
$ gid=$(( $gid_from_ls - $lowest_subgid + 1))
(In the computation it was assumed that there is only one subuid range and one subgid range)
$ echo $uid
2003
$ echo $gid
2003
The computation shows that the UID is 2003
and the GID is 2003
inside the container.
This comes as no surprise as this is what was specified before with --user=2003:2003
,
but the same computation could be used whenever a username is specified
or the --user
option is not used.
Run the container again but now with UIDs and GIDs mapped
$ subuidSize=$(( $(podman info --format "{{ range .Host.IDMappings.UIDMap }}+{{.Size }}{{end }}" ) - 1 ))
$ subgidSize=$(( $(podman info --format "{{ range .Host.IDMappings.GIDMap }}+{{.Size }}{{end }}" ) - 1 ))
$ mkdir dir1
$ chmod 777 dir1
$ podman run --rm
-v ./dir1:/dir1:Z \
--user $uid:$gid \
--uidmap $uid:0:1 \
--uidmap 0:1:$uid \
--uidmap $(($uid+1)):$(($uid+1)):$(($subuidSize-$uid)) \
--gidmap $gid:0:1 \
--gidmap 0:1:$gid \
--gidmap $(($gid+1)):$(($gid+1)):$(($subgidSize-$gid)) \
docker.io/library/ubuntu bash -c "touch /dir1/a; chmod 600 /dir1/a"
$ id -u
tester
$ id -g
tester
$ ls -l dir1/a
-rw-------. 1 tester tester 0 Jan 19 20:31 dir1/a
$
In this example the --user
option specified a rootless user in the container.
As the rootless user could also have been specified in the container image, e.g.
$ podman image inspect --format "user: {{.User}}" IMAGE
user: hpc
the same problem could also occur even without specifying --user
.
Another variant of the same problem could occur when using
--user=root:root
(the default), but where the root user creates non-root owned files
in some way (e.g by creating them themselves, or switching the effective UID to
a rootless user and then creates files).
As a non-root user you have access rights to devices, files and directories that you
want to pass into a rootless container with --device=...
, --volume=...
or --mount=..
.
Podman by default maps a non-root user inside a container to one of the user's subordinate UIDs and subordinate GIDs on the host. When the container user tries to access a file, a "Permission denied" error could occur because the container user does not have the permissions of the regular user of the host.
- Any access inside the container is rejected with "Permission denied"
for files, directories or devices passed in to the container
with
--device=..
,--volume=..
or--mount=..
, e.g.
$ mkdir dir1
$ chmod 700 dir1
$ podman run --rm -v ./dir1:/dir1:Z \
--user 2003:2003 \
docker.io/library/ubuntu ls /dir1
ls: cannot open directory '/dir1': Permission denied
We follow essentially the same solution as in the previous troubleshooting tip:
Container creates a file that is not owned by the regular UID
but for this problem the container UID and GID can't be as easily computed by mere addition and subtraction.
In other words, it might be more challenging to find out the UID and the GID inside the container that we want to map to the regular user on the host.
If the --user
option is used together with a numerical UID and GID
to specify a rootless user, we already know the answer.
If the --user
option is used together with a username and groupname,
we could look up the UID and GID in the file /etc/passwd
of the container.
If the container user is not set via --user
but instead from the
container image, we could inspect the container image
$ podman image inspect --format "user: {{.User}}" IMAGE
user: hpc
and then look it up in /etc/passwd
of the container.
If the problem occurs in a container that is started to run as root but later
switches to an effictive UID of a rootless user, it might be less
straightforward to find out the UID and the GID. Reading the
Containerfile
, Dockerfile
or the /etc/passwd
could give a clue.
To run the container with the rootless container UID and GID mapped to the user's regular UID and GID on the host follow these steps:
Set the uid
and gid
shell variables in a Bash shell to the UID and GID
of the user that will be running inside the container, e.g.
$ uid=2003
$ gid=2003
and run
$ mkdir dir1
$ echo hello > dir1/file.txt
$ chmod 700 dir1/file.txt
$ subuidSize=$(( $(podman info --format "{{ range .Host.IDMappings.UIDMap }}+{{.Size }}{{end }}" ) - 1 ))
$ subgidSize=$(( $(podman info --format "{{ range .Host.IDMappings.GIDMap }}+{{.Size }}{{end }}" ) - 1 ))
$ podman run --rm \
-v ./dir1:/dir1:Z \
--user $uid:$gid \
--uidmap $uid:0:1 \
--uidmap 0:1:$uid \
--uidmap $(($uid+1)):$(($uid+1)):$(($subuidSize-$uid)) \
--gidmap $gid:0:1 \
--gidmap 0:1:$gid \
--gidmap $(($gid+1)):$(($gid+1)):$(($subgidSize-$gid)) \
docker.io/library/alpine cat /dir1/file.txt
hello
A side-note: Using --userns=keep-id
can sometimes be an alternative solution, but it forces the regular
user's host UID to be mapped to the same UID inside the container
so it provides less flexibility than using --uidmap
and --gidmap
.
When an image in an additional store is used, it is not locked thus it can be deleted even if there are containers using it.
WARN[0000] Can't stat lower layer "/var/lib/containers/storage/overlay/l/7HS76F2P5N73FDUKUQAOJA3WI5" because it does not exist. Going through storage to recreate the missing symlinks.
It is the user responsibility to make sure images in an additional store are not deleted while being used by containers in another store.
After upgrading Podman to a newer version an issue with the earlier version of Podman still presents itself while using podman-remote.
While running podman remote commands with the most updated Podman, issues that were fixed in a prior version of Podman can arise either on the Podman client side or the Podman server side.
When upgrading Podman to a particular version for the required fixes, users often make the mistake of only upgrading the Podman client. However, suppose a setup uses podman-remote
or uses a client that communicates with the Podman server on a remote machine via the REST API. In that case, it is required to upgrade both the Podman client and the Podman server running on the remote machine. Both the Podman client and server must be upgraded to the same version.
Example: If a particular bug was fixed in v4.1.0
then the Podman client must have version v4.1.0
as well the Podman server must have version v4.1.0
.