OCI Runtime Support¶
Overview¶
OCI is an acronym for the Open Containers Initiative - an independent organization whose mandate is to develop open standards relating to containerization. To date, standardization efforts have focused on container formats and runtimes. Singularity’s compliance with respect to the OCI Image Specification is considered in detail elsewhere. It is Singularity’s compliance with the OCI Runtime Specification that is of concern here.
Briefly, compliance with respect to the OCI Runtime Specification is addressed in Singularity through the introduction of the oci
command group. Although this command group can, in principle, be used to provide a runtime that supports end users, in this initial documentation effort, emphasis is placed upon interoperability with Kubernetes; more specifically, interoperability with Kubernetes via the Singularity Container Runtime Interface.
Owing to this restricted focus, a subset of the Singularity oci
command group receives attention here; specifically:
Mounting and unmounting OCI filesystem bundles
Creating OCI compliant container instances
Some context for integration with Kubernetes via the Singularity CRI is provided at the end of the section.
Note
All commands in the oci
command group require root
privileges.
Mounted OCI Filesystem Bundles¶
Mounting an OCI Filesystem Bundle¶
BusyBox is used here for the purpose of illustration.
Suppose the Singularity Image Format (SIF) file busybox_latest.sif
exists locally. (Recall:
$ singularity pull docker://busybox
INFO: Starting build...
Getting image source signatures
Copying blob sha256:fc1a6b909f82ce4b72204198d49de3aaf757b3ab2bb823cb6e47c416b97c5985
738.13 KiB / 738.13 KiB [==================================================] 0s
Copying config sha256:5fffaf1f2c1830a6a8cf90eb27c7a1a8476b8c49b4b6261a20d6257d031ce4f3
575 B / 575 B [============================================================] 0s
Writing manifest to image destination
Storing signatures
INFO: Creating SIF file...
INFO: Build complete: busybox_latest.sif
This is one way to bootstrap creation of this image in SIF that retains a local copy - i.e., a local copy of the SIF file and a cached copy of the OCI blobs. Additional approaches and details can be found in the section Support for Docker and OCI).
For the purpose of boostrapping the creation of an OCI compliant container, this SIF file can be mounted as follows:
$ sudo singularity oci mount ./busybox_latest.sif /var/tmp/busybox
By issuing the mount
command, the root filesystem encapsulated in the SIF file busybox_latest.sif
is mounted on /var/tmp/busybox
as an overlay
file system,
$ sudo df -k
Filesystem 1K-blocks Used Available Use% Mounted on
udev 475192 0 475192 0% /dev
tmpfs 100916 1604 99312 2% /run
/dev/mapper/vagrant--vg-root 19519312 2620740 15883996 15% /
tmpfs 504560 0 504560 0% /dev/shm
tmpfs 5120 0 5120 0% /run/lock
tmpfs 504560 0 504560 0% /sys/fs/cgroup
tmpfs 100912 0 100912 0% /run/user/900
overlay 19519312 2620740 15883996 15% /var/tmp/busybox/rootfs
with permissions as follows:
$ sudo ls -ld /var/tmp/busybox
drwx------ 4 root root 4096 Apr 4 14:30 /var/tmp/busybox
Content of an OCI Compliant Filesystem Bundle¶
The expected contents of the mounted filesystem are as follows:
$ sudo ls -la /var/tmp/busybox
total 28
drwx------ 4 root root 4096 Apr 4 14:30 .
drwxrwxrwt 4 root root 4096 Apr 4 14:30 ..
-rw-rw-rw- 1 root root 9879 Apr 4 14:30 config.json
drwx------ 4 root root 4096 Apr 4 14:30 overlay
drwx------ 1 root root 4096 Apr 4 14:30 rootfs
From the perspective of the OCI runtime specification, this content is expected because it prescribes a
“… a format for encoding a container as a filesystem bundle - a set of files organized in a certain way, and containing all the necessary data and metadata for any compliant runtime to perform all standard operations against it.”
Critical to compliance with the specification is the presence of the following mandatory artifacts residing locally in a single directory:
The
config.json
file - a file of configuration data that must reside in the root of the bundle directory under this nameThe container’s root filesystem - a referenced directory
Note
Because the directory itself, i.e., /var/tmp/busybox
is not part of the bundle, the mount point can be chosen arbitrarily.
The filtered config.json
file corresponding to the OCI mounted busybox_latest.sif
container can be detailed as follows via $ sudo cat /var/tmp/busybox/config.json | jq
:
{
"ociVersion": "1.0.1-dev",
"process": {
"user": {
"uid": 0,
"gid": 0
},
"args": [
"/.singularity.d/actions/run"
],
"env": [
"PATH=/usr/local/sbin:/usr/local/bin:/usr/sbin:/usr/bin:/sbin:/bin",
"TERM=xterm"
],
"cwd": "/",
"capabilities": {
"bounding": [
"CAP_CHOWN",
"CAP_DAC_OVERRIDE",
"CAP_FSETID",
"CAP_FOWNER",
"CAP_MKNOD",
"CAP_NET_RAW",
"CAP_SETGID",
"CAP_SETUID",
"CAP_SETFCAP",
"CAP_SETPCAP",
"CAP_NET_BIND_SERVICE",
"CAP_SYS_CHROOT",
"CAP_KILL",
"CAP_AUDIT_WRITE"
],
"effective": [
"CAP_CHOWN",
"CAP_DAC_OVERRIDE",
"CAP_FSETID",
"CAP_FOWNER",
"CAP_MKNOD",
"CAP_NET_RAW",
"CAP_SETGID",
"CAP_SETUID",
"CAP_SETFCAP",
"CAP_SETPCAP",
"CAP_NET_BIND_SERVICE",
"CAP_SYS_CHROOT",
"CAP_KILL",
"CAP_AUDIT_WRITE"
],
"inheritable": [
"CAP_CHOWN",
"CAP_DAC_OVERRIDE",
"CAP_FSETID",
"CAP_FOWNER",
"CAP_MKNOD",
"CAP_NET_RAW",
"CAP_SETGID",
"CAP_SETUID",
"CAP_SETFCAP",
"CAP_SETPCAP",
"CAP_NET_BIND_SERVICE",
"CAP_SYS_CHROOT",
"CAP_KILL",
"CAP_AUDIT_WRITE"
],
"permitted": [
"CAP_CHOWN",
"CAP_DAC_OVERRIDE",
"CAP_FSETID",
"CAP_FOWNER",
"CAP_MKNOD",
"CAP_NET_RAW",
"CAP_SETGID",
"CAP_SETUID",
"CAP_SETFCAP",
"CAP_SETPCAP",
"CAP_NET_BIND_SERVICE",
"CAP_SYS_CHROOT",
"CAP_KILL",
"CAP_AUDIT_WRITE"
],
"ambient": [
"CAP_CHOWN",
"CAP_DAC_OVERRIDE",
"CAP_FSETID",
"CAP_FOWNER",
"CAP_MKNOD",
"CAP_NET_RAW",
"CAP_SETGID",
"CAP_SETUID",
"CAP_SETFCAP",
"CAP_SETPCAP",
"CAP_NET_BIND_SERVICE",
"CAP_SYS_CHROOT",
"CAP_KILL",
"CAP_AUDIT_WRITE"
]
},
"rlimits": [
{
"type": "RLIMIT_NOFILE",
"hard": 1024,
"soft": 1024
}
]
},
"root": {
"path": "/var/tmp/busybox/rootfs"
},
"hostname": "mrsdalloway",
"mounts": [
{
"destination": "/proc",
"type": "proc",
"source": "proc"
},
{
"destination": "/dev",
"type": "tmpfs",
"source": "tmpfs",
"options": [
"nosuid",
"strictatime",
"mode=755",
"size=65536k"
]
},
{
"destination": "/dev/pts",
"type": "devpts",
"source": "devpts",
"options": [
"nosuid",
"noexec",
"newinstance",
"ptmxmode=0666",
"mode=0620",
"gid=5"
]
},
{
"destination": "/dev/shm",
"type": "tmpfs",
"source": "shm",
"options": [
"nosuid",
"noexec",
"nodev",
"mode=1777",
"size=65536k"
]
},
{
"destination": "/dev/mqueue",
"type": "mqueue",
"source": "mqueue",
"options": [
"nosuid",
"noexec",
"nodev"
]
},
{
"destination": "/sys",
"type": "sysfs",
"source": "sysfs",
"options": [
"nosuid",
"noexec",
"nodev",
"ro"
]
}
],
"linux": {
"resources": {
"devices": [
{
"allow": false,
"access": "rwm"
}
]
},
"namespaces": [
{
"type": "pid"
},
{
"type": "network"
},
{
"type": "ipc"
},
{
"type": "uts"
},
{
"type": "mount"
}
],
"seccomp": {
"defaultAction": "SCMP_ACT_ERRNO",
"architectures": [
"SCMP_ARCH_X86_64",
"SCMP_ARCH_X86",
"SCMP_ARCH_X32"
],
"syscalls": [
{
"names": [
"accept",
"accept4",
"access",
"alarm",
"bind",
"brk",
"capget",
"capset",
"chdir",
"chmod",
"chown",
"chown32",
"clock_getres",
"clock_gettime",
"clock_nanosleep",
"close",
"connect",
"copy_file_range",
"creat",
"dup",
"dup2",
"dup3",
"epoll_create",
"epoll_create1",
"epoll_ctl",
"epoll_ctl_old",
"epoll_pwait",
"epoll_wait",
"epoll_wait_old",
"eventfd",
"eventfd2",
"execve",
"execveat",
"exit",
"exit_group",
"faccessat",
"fadvise64",
"fadvise64_64",
"fallocate",
"fanotify_mark",
"fchdir",
"fchmod",
"fchmodat",
"fchown",
"fchown32",
"fchownat",
"fcntl",
"fcntl64",
"fdatasync",
"fgetxattr",
"flistxattr",
"flock",
"fork",
"fremovexattr",
"fsetxattr",
"fstat",
"fstat64",
"fstatat64",
"fstatfs",
"fstatfs64",
"fsync",
"ftruncate",
"ftruncate64",
"futex",
"futimesat",
"getcpu",
"getcwd",
"getdents",
"getdents64",
"getegid",
"getegid32",
"geteuid",
"geteuid32",
"getgid",
"getgid32",
"getgroups",
"getgroups32",
"getitimer",
"getpeername",
"getpgid",
"getpgrp",
"getpid",
"getppid",
"getpriority",
"getrandom",
"getresgid",
"getresgid32",
"getresuid",
"getresuid32",
"getrlimit",
"get_robust_list",
"getrusage",
"getsid",
"getsockname",
"getsockopt",
"get_thread_area",
"gettid",
"gettimeofday",
"getuid",
"getuid32",
"getxattr",
"inotify_add_watch",
"inotify_init",
"inotify_init1",
"inotify_rm_watch",
"io_cancel",
"ioctl",
"io_destroy",
"io_getevents",
"ioprio_get",
"ioprio_set",
"io_setup",
"io_submit",
"ipc",
"kill",
"lchown",
"lchown32",
"lgetxattr",
"link",
"linkat",
"listen",
"listxattr",
"llistxattr",
"_llseek",
"lremovexattr",
"lseek",
"lsetxattr",
"lstat",
"lstat64",
"madvise",
"memfd_create",
"mincore",
"mkdir",
"mkdirat",
"mknod",
"mknodat",
"mlock",
"mlock2",
"mlockall",
"mmap",
"mmap2",
"mprotect",
"mq_getsetattr",
"mq_notify",
"mq_open",
"mq_timedreceive",
"mq_timedsend",
"mq_unlink",
"mremap",
"msgctl",
"msgget",
"msgrcv",
"msgsnd",
"msync",
"munlock",
"munlockall",
"munmap",
"nanosleep",
"newfstatat",
"_newselect",
"open",
"openat",
"pause",
"pipe",
"pipe2",
"poll",
"ppoll",
"prctl",
"pread64",
"preadv",
"prlimit64",
"pselect6",
"pwrite64",
"pwritev",
"read",
"readahead",
"readlink",
"readlinkat",
"readv",
"recv",
"recvfrom",
"recvmmsg",
"recvmsg",
"remap_file_pages",
"removexattr",
"rename",
"renameat",
"renameat2",
"restart_syscall",
"rmdir",
"rt_sigaction",
"rt_sigpending",
"rt_sigprocmask",
"rt_sigqueueinfo",
"rt_sigreturn",
"rt_sigsuspend",
"rt_sigtimedwait",
"rt_tgsigqueueinfo",
"sched_getaffinity",
"sched_getattr",
"sched_getparam",
"sched_get_priority_max",
"sched_get_priority_min",
"sched_getscheduler",
"sched_rr_get_interval",
"sched_setaffinity",
"sched_setattr",
"sched_setparam",
"sched_setscheduler",
"sched_yield",
"seccomp",
"select",
"semctl",
"semget",
"semop",
"semtimedop",
"send",
"sendfile",
"sendfile64",
"sendmmsg",
"sendmsg",
"sendto",
"setfsgid",
"setfsgid32",
"setfsuid",
"setfsuid32",
"setgid",
"setgid32",
"setgroups",
"setgroups32",
"setitimer",
"setpgid",
"setpriority",
"setregid",
"setregid32",
"setresgid",
"setresgid32",
"setresuid",
"setresuid32",
"setreuid",
"setreuid32",
"setrlimit",
"set_robust_list",
"setsid",
"setsockopt",
"set_thread_area",
"set_tid_address",
"setuid",
"setuid32",
"setxattr",
"shmat",
"shmctl",
"shmdt",
"shmget",
"shutdown",
"sigaltstack",
"signalfd",
"signalfd4",
"sigreturn",
"socket",
"socketcall",
"socketpair",
"splice",
"stat",
"stat64",
"statfs",
"statfs64",
"symlink",
"symlinkat",
"sync",
"sync_file_range",
"syncfs",
"sysinfo",
"syslog",
"tee",
"tgkill",
"time",
"timer_create",
"timer_delete",
"timerfd_create",
"timerfd_gettime",
"timerfd_settime",
"timer_getoverrun",
"timer_gettime",
"timer_settime",
"times",
"tkill",
"truncate",
"truncate64",
"ugetrlimit",
"umask",
"uname",
"unlink",
"unlinkat",
"utime",
"utimensat",
"utimes",
"vfork",
"vmsplice",
"wait4",
"waitid",
"waitpid",
"write",
"writev"
],
"action": "SCMP_ACT_ALLOW"
},
{
"names": [
"personality"
],
"action": "SCMP_ACT_ALLOW",
"args": [
{
"index": 0,
"value": 0,
"op": "SCMP_CMP_EQ"
},
{
"index": 0,
"value": 8,
"op": "SCMP_CMP_EQ"
},
{
"index": 0,
"value": 4294967295,
"op": "SCMP_CMP_EQ"
}
]
},
{
"names": [
"chroot"
],
"action": "SCMP_ACT_ALLOW"
},
{
"names": [
"clone"
],
"action": "SCMP_ACT_ALLOW",
"args": [
{
"index": 0,
"value": 2080505856,
"op": "SCMP_CMP_MASKED_EQ"
}
]
},
{
"names": [
"arch_prctl"
],
"action": "SCMP_ACT_ALLOW"
},
{
"names": [
"modify_ldt"
],
"action": "SCMP_ACT_ALLOW"
}
]
}
}
}
Furthermore, and through use of $ sudo cat /var/tmp/busybox/config.json | jq [.root.path]
, the property
[
"/var/tmp/busybox/rootfs"
]
identifies /var/tmp/busybox/rootfs
as the container’s root filesystem, as required by the standard; this filesystem has contents:
$ sudo ls /var/tmp/busybox/rootfs
bin dev environment etc home proc root singularity sys tmp usr var
Note
environment
and singularity
above are symbolic links to the .singularity.d
directory.
Beyond root.path
, the config.json
file includes a multitude of additional properties - for example:
ociVersion
- a mandatory property that identifies the version of the OCI runtime specification that the bundle is compliant with
process
- an optional property that specifies the container process. When invoked via Singularity, subproperties such asargs
are populated by making use of the contents of the.singularity.d
directory, e.g. via$ sudo cat /var/tmp/busybox/config.json | jq [.process.args]
:[ [ "/.singularity.d/actions/run" ] ]where
run
equates to the familiar runscript for this container. If image creation is bootstrapped via a Docker or OCI agent, Singularity will make use ofENTRYPOINT
orCMD
(from the OCI image) to populateargs
; for additional discussion, please refer to Directing Execution in the section Support for Docker and OCI.
For a comprehensive discussion of all the config.json
file properties, refer to the implementation guide.
Technically, the overlay
directory was not content expected of an OCI compliant filesystem bundle. As detailed in the section dedicated to Persistent Overlays, these directories allow for the introduction of
a writable file system on an otherwise immutable read-only container; thus they permit the illusion of read-write access.
Note
SIF is stated to be an extensible format; by encapsulating a filesystem bundle that conforms with the OCI runtime specification, this extensibility is evident.
Creating OCI Compliant Container Instances¶
SIF files encapsulate the OCI runtime. By ‘OCI mounting’ a SIF file (see above), this encapsulated runtime is revealed; please refer to the note below for additional details. Once revealed, the filesystem bundle can be used to bootstrap the creation of an OCI compliant container instance as follows:
$ sudo singularity oci create -b /var/tmp/busybox busybox1
Note
Data for the config.json
file exists within the SIF file as a descriptor for images pulled or built from Docker/OCI registries. For images sourced elsewhere, a default config.json
file is created when the singularity oci mount ...
command is issued.
Upon invocation, singularity oci mount ...
also mounts the root filesystem stored in the SIF file on /bundle/rootfs
, and establishes an overlay filesystem on the mount point /bundle/overlay
.
In this example, the filesystem bundle is located in the directory /var/tmp/busybox
- i.e., the mount point identified above with respect to ‘OCI mounting’. The config.json
file, along with the rootfs
and overlay
filesystems, are all employed in the bootstrap process. The instance is named busybox1
in this example.
Note
The outcome of this creation request is truly a container instance. Multiple instances of the same container can easily be created by simply changing the name of the instance upon subsequent invocation requests.
The state
of the container instance can be determined via $ sudo singularity oci state busybox1
:
{
"ociVersion": "1.0.1-dev",
"id": "busybox1",
"status": "created",
"pid": 6578,
"bundle": "/var/tmp/busybox",
"createdAt": 1554389921452964253,
"attachSocket": "/var/run/singularity/instances/root/busybox1/attach.sock",
"controlSocket": "/var/run/singularity/instances/root/busybox1/control.sock"
}
Container state, as conveyed via these properties, is in compliance with the OCI runtime specification as detailed here.
The create
command has a number of options available. Of these, real-time logging to a file is likely to be of particular value - e.g., in deployments where auditing requirements exist.
Unmounting OCI Filesystem Bundles¶
To unmount a mounted OCI filesystem bundle, the following command should be issued:
$ sudo singularity oci umount /var/tmp/busybox
Note
The argument provided to oci umount
above is the name of the bundle path, /var/tmp/busybox
, as opposed to the mount point for the overlay filesystem, /var/tmp/busybox/rootfs
.
Kubernetes Integration¶
As noted at the outset here, in documenting support for an OCI runtime in Singularity, the impetus is initially derived from the requirement to integrate with Kubernetes. Simply stated, Kubernetes is an open-source system for orchestrating containers; developed originally at Google, Kubernetes was contributed as seed technology to the Cloud Native Compute Foundation (CNCF). At this point, Kubernetes is regarded as a Graduated Project by CNCF, and is being used widely in production deployments. Even though Kubernetes emphasizes an orientation around services, it is appealing to those seeking to orchestrate containers having compute-driven requirements. Furthermore, emerging classes of workload in AI for example, appear to have requirements that are best addressed by a combination of service and traditional HPC infrastructures. Thus there is ample existing, as well as emerging, interest in integrating Singularity containers with Kubernetes.
The connection with support for the OCI runtime documented here, within the context of a Singularity-Kubernetes integration, can be best established through an architectural schematic. Dating back to the introduction of a Container Runtime Interface (CRI) for Kubernetes in late 2016, the schematic below is a modified version of the original presented in a Kubernetes blog post. The lower branch of this schematic is essentially a reproduction of the original; it does however, place emphasis on OCI compliance in terms of the CRI and containers (the runtime as well as their instances).
From this schematic it is evident that integrating Singularity containers with Kubernetes requires the following efforts:
Implementation of a CRI for Singularity
Implementation of an OCI runtime in Singularity
The implementation of a CRI for Singularity is the emphasis of a separate and distinct open source project; the implementation of this CRI is documented here. For the rationale conveyed through the architectural schematic, Singularity CRI’s dependence upon Singularity with OCI runtime support is made clear as an installation prerequisite. User-facing documentation for Singularity CRI details usage in a Kubernetes context - usage, of course, that involves orchestration of a Singularity container obtained from the Sylabs Cloud Container Library. Because the entire Kubernetes-based deployment can exist within a single instance of a Singularity container, Singularity CRI can be easily evaluated via Sykube; inspired by Minikube, use of Sykube is included in the documentation for Singularity CRI.
Documenting the implementation of an OCI-compliant runtime for Singularity has been the emphasis here. Although this standalone runtime can be used by end users independent of anything to do with Singularity and Kubernetes, the primary purpose here has been documenting it within this integrated context. In other words, by making use of the OCI runtime presented by Singularity, commands originating from Kubernetes (see, e.g., Basic Usage in the Singularity CRI documentation) have impact ultimately on Singularity containers via the CRI. Singularity CRI is implemented as a gRPC server - i.e., a persistent service available to Kubelets (node agents). Taken together, this integration allows Singularity containers to be manipulated directly from Kubernetes.