cap/names.go - pub/scm/linux/kernel/git/morgan/libcap - Git at Google

 package cap

 /* ** DO NOT EDIT THIS FILE. IT WAS AUTO-GENERATED BY LIBCAP'S GO BUILDER (mknames.go) ** */

 // NamedCount holds the number of capability values with official
 // names known at the time this libcap/cap version, was released. The
 // "../libcap/cap" package is fully able to manipulate higher numbered
 // capability values by numerical value. However, if you find
 // cap.NamedCount < cap.MaxBits(), it is probably time to upgrade this
 // package on your system.
 //
 // FWIW the userspace tool '/sbin/capsh' also contains a runtime check
 // for the condition that libcap is behind the running kernel in this
 // way.
 const NamedCount = 41

 // CHOWN etc., are the named capability values of the Linux
 // kernel. The canonical source for each name is the
 // "uapi/linux/capabilities.h" file.  Some values may not be available
 // (yet) where the kernel is older.  The actual number of capabities
 // supported by the running kernel can be obtained using the
 // cap.MaxBits() function.
 const (
 	// CHOWN allows a process to arbitrarily change the user and
 	// group ownership of a file.
 	CHOWN Value = iota

 	// DAC_OVERRIDE allows a process to override of all Discretionary
 	// Access Control (DAC) access, including ACL execute
 	// access. That is read, write or execute files that the
 	// process would otherwise not have access to. This
 	// excludes DAC access covered by cap.LINUX_IMMUTABLE.
 	DAC_OVERRIDE

 	// DAC_READ_SEARCH allows a process to override all DAC restrictions
 	// limiting the read and search of files and
 	// directories. This excludes DAC access covered by
 	// cap.LINUX_IMMUTABLE.
 	DAC_READ_SEARCH

 	// FOWNER allows a process to perform operations on files, even
 	// where file owner ID should otherwise need be equal to
 	// the UID, except where cap.FSETID is applicable. It
 	// doesn't override MAC and DAC restrictions.
 	FOWNER

 	// FSETID allows a process to set the S_ISUID and S_ISUID bits of
 	// the file permissions, even when the process' effective
 	// UID or GID/supplementary GIDs do not match that of the
 	// file.
 	FSETID

 	// KILL allows a process to sent a kill(2) signal to any other
 	// process - overriding the limitation that there be a
 	// [E]UID match between source and target process.
 	KILL

 	// SETGID allows a process to freely manipulate its own GIDs:
 	//   - arbitrarily set the GID, EGID, REGID, RESGID values
 	//   - arbitrarily set the supplementary GIDs
 	//   - allows the forging of GID credentials passed over a
 	//     socket
 	SETGID

 	// SETUID allows a process to freely manipulate its own UIDs:
 	//   - arbitraily set the UID, EUID, REUID and RESUID
 	//     values
 	//   - allows the forging of UID credentials passed over a
 	//     socket
 	SETUID

 	// SETPCAP allows a process to freely manipulate its inheritable
 	// capabilities.  Linux supports the POSIX.1e Inheritable
 	// set, as well as Bounding and Ambient Linux extension
 	// vectors. This capability permits dropping bits from the
 	// Bounding vector. It also permits the process to raise
 	// Ambient vector bits that are both raised in the
 	// Permitted and Inheritable sets of the process. This
 	// capability cannot be used to raise Permitted bits, or
 	// Effective bits beyond those already present in the
 	// process' permitted set.
 	//
 	// [Historical note: prior to the advent of file
 	// capabilities (2008), this capability was suppressed by
 	// default, as its unsuppressed behavior was not
 	// auditable: it could asynchronously grant its own
 	// Permitted capabilities to and remove capabilities from
 	// other processes arbitraily. The former leads to
 	// undefined behavior, and the latter is better served by
 	// the kill system call.]
 	SETPCAP

 	// LINUX_IMMUTABLE allows a process to modify the S_IMMUTABLE and
 	// S_APPEND file attributes.
 	LINUX_IMMUTABLE

 	// NET_BIND_SERVICE allows a process to bind to privileged ports:
 	//   - TCP/UDP sockets below 1024
 	//   - ATM VCIs below 32
 	NET_BIND_SERVICE

 	// NET_BROADCAST allows a process to broadcast to the network and to
 	// listen to multicast.
 	NET_BROADCAST

 	// NET_ADMIN allows a process to perform network configuration
 	// operations:
 	//   - interface configuration
 	//   - administration of IP firewall, masquerading and
 	//     accounting
 	//   - setting debug options on sockets
 	//   - modification of routing tables
 	//   - setting arbitrary process, and process group
 	//     ownership on sockets
 	//   - binding to any address for transparent proxying
 	//     (this is also allowed via cap.NET_RAW)
 	//   - setting TOS (Type of service)
 	//   - setting promiscuous mode
 	//   - clearing driver statistics
 	//   - multicasing
 	//   - read/write of device-specific registers
 	//   - activation of ATM control sockets
 	NET_ADMIN

 	// NET_RAW allows a process to use raw networking:
 	//   - RAW sockets
 	//   - PACKET sockets
 	//   - binding to any address for transparent proxying
 	//     (also permitted via cap.NET_ADMIN)
 	NET_RAW

 	// IPC_LOCK allows a process to lock shared memory segments for IPC
 	// purposes.  Also enables mlock and mlockall system
 	// calls.
 	IPC_LOCK

 	// IPC_OWNER allows a process to override IPC ownership checks.
 	IPC_OWNER

 	// SYS_MODULE allows a process to initiate the loading and unloading
 	// of kernel modules. This capability can effectively
 	// modify kernel without limit.
 	SYS_MODULE

 	// SYS_RAWIO allows a process to perform raw IO:
 	//   - permit ioper/iopl access
 	//   - permit sending USB messages to any device via
 	//     /dev/bus/usb
 	SYS_RAWIO

 	// SYS_CHROOT allows a process to perform a chroot syscall to change
 	// the effective root of the process' file system:
 	// redirect to directory "/" to some other location.
 	SYS_CHROOT

 	// SYS_PTRACE allows a process to perform a ptrace() of any other
 	// process.
 	SYS_PTRACE

 	// SYS_PACCT allows a process to configure process accounting.
 	SYS_PACCT

 	// SYS_ADMIN allows a process to perform a somewhat arbitrary
 	// grab-bag of privileged operations. Over time, this
 	// capability should weaken as specific capabilities are
 	// created for subsets of cap.SYS_ADMINs functionality:
 	//   - configuration of the secure attention key
 	//   - administration of the random device
 	//   - examination and configuration of disk quotas
 	//   - setting the domainname
 	//   - setting the hostname
 	//   - calling bdflush()
 	//   - mount() and umount(), setting up new SMB connection
 	//   - some autofs root ioctls
 	//   - nfsservctl
 	//   - VM86_REQUEST_IRQ
 	//   - to read/write pci config on alpha
 	//   - irix_prctl on mips (setstacksize)
 	//   - flushing all cache on m68k (sys_cacheflush)
 	//   - removing semaphores
 	//   - Used instead of cap.CHOWN to "chown" IPC message
 	//     queues, semaphores and shared memory
 	//   - locking/unlocking of shared memory segment
 	//   - turning swap on/off
 	//   - forged pids on socket credentials passing
 	//   - setting readahead and flushing buffers on block
 	//     devices
 	//   - setting geometry in floppy driver
 	//   - turning DMA on/off in xd driver
 	//   - administration of md devices (mostly the above, but
 	//     some extra ioctls)
 	//   - tuning the ide driver
 	//   - access to the nvram device
 	//   - administration of apm_bios, serial and bttv (TV)
 	//     device
 	//   - manufacturer commands in isdn CAPI support driver
 	//   - reading non-standardized portions of PCI
 	//     configuration space
 	//   - DDI debug ioctl on sbpcd driver
 	//   - setting up serial ports
 	//   - sending raw qic-117 commands
 	//   - enabling/disabling tagged queuing on SCSI
 	//     controllers and sending arbitrary SCSI commands
 	//   - setting encryption key on loopback filesystem
 	//   - setting zone reclaim policy
 	SYS_ADMIN

 	// SYS_BOOT allows a process to initiate a reboot of the system.
 	SYS_BOOT

 	// SYS_NICE allows a process to maipulate the execution priorities
 	// of arbitrary processes:
 	//   - those involving different UIDs
 	//   - setting their CPU affinity
 	//   - alter the FIFO vs. round-robin (realtime)
 	//     scheduling for itself and other processes.
 	SYS_NICE

 	// SYS_RESOURCE allows a process to adjust resource related parameters
 	// of processes and the system:
 	//   - set and override resource limits
 	//   - override quota limits
 	//   - override the reserved space on ext2 filesystem
 	//     (this can also be achieved via cap.FSETID)
 	//   - modify the data journaling mode on ext3 filesystem,
 	//     which uses journaling resources
 	//   - override size restrictions on IPC message queues
 	//   - configure more than 64Hz interrupts from the
 	//     real-time clock
 	//   - override the maximum number of consoles for console
 	//     allocation
 	//   - override the maximum number of keymaps
 	//
 	//
 	SYS_RESOURCE

 	// SYS_TIME allows a process to perform time manipulation of clocks:
 	//   - alter the system clock
 	//   - enable irix_stime on MIPS
 	//   - set the real-time clock
 	SYS_TIME

 	// SYS_TTY_CONFIG allows a process to manipulate tty devices:
 	//   - configure tty devices
 	//   - perform vhangup() of a tty
 	SYS_TTY_CONFIG

 	// MKNOD allows a process to perform privileged operations with
 	// the mknod() system call.
 	MKNOD

 	// LEASE allows a process to take leases on files.
 	LEASE

 	// AUDIT_WRITE allows a process to write to the audit log via a
 	// unicast netlink socket.
 	AUDIT_WRITE

 	// AUDIT_CONTROL allows a process to configure audit logging via a
 	// unicast netlink socket.
 	AUDIT_CONTROL

 	// SETFCAP allows a process to set capabilities on files.
 	SETFCAP

 	// MAC_OVERRIDE allows a process to override Manditory Access Control
 	// (MAC) access. Not all kernels are configured with a MAC
 	// mechanism, but this is the capability reserved for
 	// overriding them.
 	MAC_OVERRIDE

 	// MAC_ADMIN allows a process to configure the Mandatory Access
 	// Control (MAC) policy. Not all kernels are configured
 	// with a MAC enabled, but if they are this capability is
 	// reserved for code to perform administration tasks.
 	MAC_ADMIN

 	// SYSLOG allows a process to configure the kernel's syslog
 	// (printk) behavior.
 	SYSLOG

 	// WAKE_ALARM allows a process to trigger something that can wake the
 	// system up.
 	WAKE_ALARM

 	// BLOCK_SUSPEND allows a process to block system suspends - prevent the
 	// system from entering a lower power state.
 	BLOCK_SUSPEND

 	// AUDIT_READ allows a process to read the audit log via a multicast
 	// netlink socket.
 	AUDIT_READ

 	// PERFMON allows a process to enable observability of privileged
 	// operations related to performance. The mechanisms
 	// include perf_events, i915_perf and other kernel
 	// subsystems.
 	PERFMON

 	// BPF allows a process to manipulate aspects of the kernel
 	// enhanced Berkeley Packet Filter (BPF) system. This is
 	// an execution subsystem of the kernel, that manages BPF
 	// programs. cap.BPF permits a process to:
 	//   - create all types of BPF maps
 	//   - advanced verifier features:
 	//     - indirect variable access
 	//     - bounded loops
 	//     - BPF to BPF function calls
 	//     - scalar precision tracking
 	//     - larger complexity limits
 	//     - dead code elimination
 	//     - potentially other features
 	//
 	// Other capabilities can be used together with cap.BFP to
 	// further manipulate the BPF system:
 	//   - cap.PERFMON relaxes the verifier checks as follows:
 	//     - BPF programs can use pointer-to-integer
 	//       conversions
 	//     - speculation attack hardening measures can be
 	//       bypassed
 	//     - bpf_probe_read to read arbitrary kernel memory is
 	//       permitted
 	//     - bpf_trace_printk to print the content of kernel
 	//       memory
 	//   - cap.SYS_ADMIN permits the following:
 	//     - use of bpf_probe_write_user
 	//     - iteration over the system-wide loaded programs,
 	//       maps, links BTFs and convert their IDs to file
 	//       descriptors.
 	//   - cap.PERFMON is required to load tracing programs.
 	//   - cap.NET_ADMIN is required to load networking
 	//     programs.
 	BPF

 	// CHECKPOINT_RESTORE allows a process to perform checkpoint
 	// and restore operations. Also permits
 	// explicit PID control via clone3() and
 	// also writing to ns_last_pid.
 	CHECKPOINT_RESTORE
 )

 var names = map[Value]string{
 	CHOWN:              "cap_chown",
 	DAC_OVERRIDE:       "cap_dac_override",
 	DAC_READ_SEARCH:    "cap_dac_read_search",
 	FOWNER:             "cap_fowner",
 	FSETID:             "cap_fsetid",
 	KILL:               "cap_kill",
 	SETGID:             "cap_setgid",
 	SETUID:             "cap_setuid",
 	SETPCAP:            "cap_setpcap",
 	LINUX_IMMUTABLE:    "cap_linux_immutable",
 	NET_BIND_SERVICE:   "cap_net_bind_service",
 	NET_BROADCAST:      "cap_net_broadcast",
 	NET_ADMIN:          "cap_net_admin",
 	NET_RAW:            "cap_net_raw",
 	IPC_LOCK:           "cap_ipc_lock",
 	IPC_OWNER:          "cap_ipc_owner",
 	SYS_MODULE:         "cap_sys_module",
 	SYS_RAWIO:          "cap_sys_rawio",
 	SYS_CHROOT:         "cap_sys_chroot",
 	SYS_PTRACE:         "cap_sys_ptrace",
 	SYS_PACCT:          "cap_sys_pacct",
 	SYS_ADMIN:          "cap_sys_admin",
 	SYS_BOOT:           "cap_sys_boot",
 	SYS_NICE:           "cap_sys_nice",
 	SYS_RESOURCE:       "cap_sys_resource",
 	SYS_TIME:           "cap_sys_time",
 	SYS_TTY_CONFIG:     "cap_sys_tty_config",
 	MKNOD:              "cap_mknod",
 	LEASE:              "cap_lease",
 	AUDIT_WRITE:        "cap_audit_write",
 	AUDIT_CONTROL:      "cap_audit_control",
 	SETFCAP:            "cap_setfcap",
 	MAC_OVERRIDE:       "cap_mac_override",
 	MAC_ADMIN:          "cap_mac_admin",
 	SYSLOG:             "cap_syslog",
 	WAKE_ALARM:         "cap_wake_alarm",
 	BLOCK_SUSPEND:      "cap_block_suspend",
 	AUDIT_READ:         "cap_audit_read",
 	PERFMON:            "cap_perfmon",
 	BPF:                "cap_bpf",
 	CHECKPOINT_RESTORE: "cap_checkpoint_restore",
 }

 var bits = map[string]Value{
 	"cap_chown":              CHOWN,
 	"cap_dac_override":       DAC_OVERRIDE,
 	"cap_dac_read_search":    DAC_READ_SEARCH,
 	"cap_fowner":             FOWNER,
 	"cap_fsetid":             FSETID,
 	"cap_kill":               KILL,
 	"cap_setgid":             SETGID,
 	"cap_setuid":             SETUID,
 	"cap_setpcap":            SETPCAP,
 	"cap_linux_immutable":    LINUX_IMMUTABLE,
 	"cap_net_bind_service":   NET_BIND_SERVICE,
 	"cap_net_broadcast":      NET_BROADCAST,
 	"cap_net_admin":          NET_ADMIN,
 	"cap_net_raw":            NET_RAW,
 	"cap_ipc_lock":           IPC_LOCK,
 	"cap_ipc_owner":          IPC_OWNER,
 	"cap_sys_module":         SYS_MODULE,
 	"cap_sys_rawio":          SYS_RAWIO,
 	"cap_sys_chroot":         SYS_CHROOT,
 	"cap_sys_ptrace":         SYS_PTRACE,
 	"cap_sys_pacct":          SYS_PACCT,
 	"cap_sys_admin":          SYS_ADMIN,
 	"cap_sys_boot":           SYS_BOOT,
 	"cap_sys_nice":           SYS_NICE,
 	"cap_sys_resource":       SYS_RESOURCE,
 	"cap_sys_time":           SYS_TIME,
 	"cap_sys_tty_config":     SYS_TTY_CONFIG,
 	"cap_mknod":              MKNOD,
 	"cap_lease":              LEASE,
 	"cap_audit_write":        AUDIT_WRITE,
 	"cap_audit_control":      AUDIT_CONTROL,
 	"cap_setfcap":            SETFCAP,
 	"cap_mac_override":       MAC_OVERRIDE,
 	"cap_mac_admin":          MAC_ADMIN,
 	"cap_syslog":             SYSLOG,
 	"cap_wake_alarm":         WAKE_ALARM,
 	"cap_block_suspend":      BLOCK_SUSPEND,
 	"cap_audit_read":         AUDIT_READ,
 	"cap_perfmon":            PERFMON,
 	"cap_bpf":                BPF,
 	"cap_checkpoint_restore": CHECKPOINT_RESTORE,
 }
	package cap

	/* DO NOT EDIT THIS FILE. IT WAS AUTO-GENERATED BY LIBCAP'S GO BUILDER (mknames.go) */

	// NamedCount holds the number of capability values with official
	// names known at the time this libcap/cap version, was released. The
	// "../libcap/cap" package is fully able to manipulate higher numbered
	// capability values by numerical value. However, if you find
	// cap.NamedCount < cap.MaxBits(), it is probably time to upgrade this
	// package on your system.
	//
	// FWIW the userspace tool '/sbin/capsh' also contains a runtime check
	// for the condition that libcap is behind the running kernel in this
	// way.
	const NamedCount = 41

	// CHOWN etc., are the named capability values of the Linux
	// kernel. The canonical source for each name is the
	// "uapi/linux/capabilities.h" file. Some values may not be available
	// (yet) where the kernel is older. The actual number of capabities
	// supported by the running kernel can be obtained using the
	// cap.MaxBits() function.
	const (
	// CHOWN allows a process to arbitrarily change the user and
	// group ownership of a file.
	CHOWN Value = iota

	// DAC_OVERRIDE allows a process to override of all Discretionary
	// Access Control (DAC) access, including ACL execute
	// access. That is read, write or execute files that the
	// process would otherwise not have access to. This
	// excludes DAC access covered by cap.LINUX_IMMUTABLE.
	DAC_OVERRIDE

	// DAC_READ_SEARCH allows a process to override all DAC restrictions
	// limiting the read and search of files and
	// directories. This excludes DAC access covered by
	// cap.LINUX_IMMUTABLE.
	DAC_READ_SEARCH

	// FOWNER allows a process to perform operations on files, even
	// where file owner ID should otherwise need be equal to
	// the UID, except where cap.FSETID is applicable. It
	// doesn't override MAC and DAC restrictions.
	FOWNER

	// FSETID allows a process to set the S_ISUID and S_ISUID bits of
	// the file permissions, even when the process' effective
	// UID or GID/supplementary GIDs do not match that of the
	// file.
	FSETID

	// KILL allows a process to sent a kill(2) signal to any other
	// process - overriding the limitation that there be a
	// [E]UID match between source and target process.
	KILL

	// SETGID allows a process to freely manipulate its own GIDs:
	// - arbitrarily set the GID, EGID, REGID, RESGID values
	// - arbitrarily set the supplementary GIDs
	// - allows the forging of GID credentials passed over a
	// socket
	SETGID

	// SETUID allows a process to freely manipulate its own UIDs:
	// - arbitraily set the UID, EUID, REUID and RESUID
	// values
	// - allows the forging of UID credentials passed over a
	// socket
	SETUID

	// SETPCAP allows a process to freely manipulate its inheritable
	// capabilities. Linux supports the POSIX.1e Inheritable
	// set, as well as Bounding and Ambient Linux extension
	// vectors. This capability permits dropping bits from the
	// Bounding vector. It also permits the process to raise
	// Ambient vector bits that are both raised in the
	// Permitted and Inheritable sets of the process. This
	// capability cannot be used to raise Permitted bits, or
	// Effective bits beyond those already present in the
	// process' permitted set.
	//
	// [Historical note: prior to the advent of file
	// capabilities (2008), this capability was suppressed by
	// default, as its unsuppressed behavior was not
	// auditable: it could asynchronously grant its own
	// Permitted capabilities to and remove capabilities from
	// other processes arbitraily. The former leads to
	// undefined behavior, and the latter is better served by
	// the kill system call.]
	SETPCAP

	// LINUX_IMMUTABLE allows a process to modify the S_IMMUTABLE and
	// S_APPEND file attributes.
	LINUX_IMMUTABLE

	// NET_BIND_SERVICE allows a process to bind to privileged ports:
	// - TCP/UDP sockets below 1024
	// - ATM VCIs below 32
	NET_BIND_SERVICE

	// NET_BROADCAST allows a process to broadcast to the network and to
	// listen to multicast.
	NET_BROADCAST

	// NET_ADMIN allows a process to perform network configuration
	// operations:
	// - interface configuration
	// - administration of IP firewall, masquerading and
	// accounting
	// - setting debug options on sockets
	// - modification of routing tables
	// - setting arbitrary process, and process group
	// ownership on sockets
	// - binding to any address for transparent proxying
	// (this is also allowed via cap.NET_RAW)
	// - setting TOS (Type of service)
	// - setting promiscuous mode
	// - clearing driver statistics
	// - multicasing
	// - read/write of device-specific registers
	// - activation of ATM control sockets
	NET_ADMIN

	// NET_RAW allows a process to use raw networking:
	// - RAW sockets
	// - PACKET sockets
	// - binding to any address for transparent proxying
	// (also permitted via cap.NET_ADMIN)
	NET_RAW

	// IPC_LOCK allows a process to lock shared memory segments for IPC
	// purposes. Also enables mlock and mlockall system
	// calls.
	IPC_LOCK

	// IPC_OWNER allows a process to override IPC ownership checks.
	IPC_OWNER

	// SYS_MODULE allows a process to initiate the loading and unloading
	// of kernel modules. This capability can effectively
	// modify kernel without limit.
	SYS_MODULE

	// SYS_RAWIO allows a process to perform raw IO:
	// - permit ioper/iopl access
	// - permit sending USB messages to any device via
	// /dev/bus/usb
	SYS_RAWIO

	// SYS_CHROOT allows a process to perform a chroot syscall to change
	// the effective root of the process' file system:
	// redirect to directory "/" to some other location.
	SYS_CHROOT

	// SYS_PTRACE allows a process to perform a ptrace() of any other
	// process.
	SYS_PTRACE

	// SYS_PACCT allows a process to configure process accounting.
	SYS_PACCT

	// SYS_ADMIN allows a process to perform a somewhat arbitrary
	// grab-bag of privileged operations. Over time, this
	// capability should weaken as specific capabilities are
	// created for subsets of cap.SYS_ADMINs functionality:
	// - configuration of the secure attention key
	// - administration of the random device
	// - examination and configuration of disk quotas
	// - setting the domainname
	// - setting the hostname
	// - calling bdflush()
	// - mount() and umount(), setting up new SMB connection
	// - some autofs root ioctls
	// - nfsservctl
	// - VM86_REQUEST_IRQ
	// - to read/write pci config on alpha
	// - irix_prctl on mips (setstacksize)
	// - flushing all cache on m68k (sys_cacheflush)
	// - removing semaphores
	// - Used instead of cap.CHOWN to "chown" IPC message
	// queues, semaphores and shared memory
	// - locking/unlocking of shared memory segment
	// - turning swap on/off
	// - forged pids on socket credentials passing
	// - setting readahead and flushing buffers on block
	// devices
	// - setting geometry in floppy driver
	// - turning DMA on/off in xd driver
	// - administration of md devices (mostly the above, but
	// some extra ioctls)
	// - tuning the ide driver
	// - access to the nvram device
	// - administration of apm_bios, serial and bttv (TV)
	// device
	// - manufacturer commands in isdn CAPI support driver
	// - reading non-standardized portions of PCI
	// configuration space
	// - DDI debug ioctl on sbpcd driver
	// - setting up serial ports
	// - sending raw qic-117 commands
	// - enabling/disabling tagged queuing on SCSI
	// controllers and sending arbitrary SCSI commands
	// - setting encryption key on loopback filesystem
	// - setting zone reclaim policy
	SYS_ADMIN

	// SYS_BOOT allows a process to initiate a reboot of the system.
	SYS_BOOT

	// SYS_NICE allows a process to maipulate the execution priorities
	// of arbitrary processes:
	// - those involving different UIDs
	// - setting their CPU affinity
	// - alter the FIFO vs. round-robin (realtime)
	// scheduling for itself and other processes.
	SYS_NICE

	// SYS_RESOURCE allows a process to adjust resource related parameters
	// of processes and the system:
	// - set and override resource limits
	// - override quota limits
	// - override the reserved space on ext2 filesystem
	// (this can also be achieved via cap.FSETID)
	// - modify the data journaling mode on ext3 filesystem,
	// which uses journaling resources
	// - override size restrictions on IPC message queues
	// - configure more than 64Hz interrupts from the
	// real-time clock
	// - override the maximum number of consoles for console
	// allocation
	// - override the maximum number of keymaps
	//
	//
	SYS_RESOURCE

	// SYS_TIME allows a process to perform time manipulation of clocks:
	// - alter the system clock
	// - enable irix_stime on MIPS
	// - set the real-time clock
	SYS_TIME

	// SYS_TTY_CONFIG allows a process to manipulate tty devices:
	// - configure tty devices
	// - perform vhangup() of a tty
	SYS_TTY_CONFIG

	// MKNOD allows a process to perform privileged operations with
	// the mknod() system call.
	MKNOD

	// LEASE allows a process to take leases on files.
	LEASE

	// AUDIT_WRITE allows a process to write to the audit log via a
	// unicast netlink socket.
	AUDIT_WRITE

	// AUDIT_CONTROL allows a process to configure audit logging via a
	// unicast netlink socket.
	AUDIT_CONTROL

	// SETFCAP allows a process to set capabilities on files.
	SETFCAP

	// MAC_OVERRIDE allows a process to override Manditory Access Control
	// (MAC) access. Not all kernels are configured with a MAC
	// mechanism, but this is the capability reserved for
	// overriding them.
	MAC_OVERRIDE

	// MAC_ADMIN allows a process to configure the Mandatory Access
	// Control (MAC) policy. Not all kernels are configured
	// with a MAC enabled, but if they are this capability is
	// reserved for code to perform administration tasks.
	MAC_ADMIN

	// SYSLOG allows a process to configure the kernel's syslog
	// (printk) behavior.
	SYSLOG

	// WAKE_ALARM allows a process to trigger something that can wake the
	// system up.
	WAKE_ALARM

	// BLOCK_SUSPEND allows a process to block system suspends - prevent the
	// system from entering a lower power state.
	BLOCK_SUSPEND

	// AUDIT_READ allows a process to read the audit log via a multicast
	// netlink socket.
	AUDIT_READ

	// PERFMON allows a process to enable observability of privileged
	// operations related to performance. The mechanisms
	// include perf_events, i915_perf and other kernel
	// subsystems.
	PERFMON

	// BPF allows a process to manipulate aspects of the kernel
	// enhanced Berkeley Packet Filter (BPF) system. This is
	// an execution subsystem of the kernel, that manages BPF
	// programs. cap.BPF permits a process to:
	// - create all types of BPF maps
	// - advanced verifier features:
	// - indirect variable access
	// - bounded loops
	// - BPF to BPF function calls
	// - scalar precision tracking
	// - larger complexity limits
	// - dead code elimination
	// - potentially other features
	//
	// Other capabilities can be used together with cap.BFP to
	// further manipulate the BPF system:
	// - cap.PERFMON relaxes the verifier checks as follows:
	// - BPF programs can use pointer-to-integer
	// conversions
	// - speculation attack hardening measures can be
	// bypassed
	// - bpf_probe_read to read arbitrary kernel memory is
	// permitted
	// - bpf_trace_printk to print the content of kernel
	// memory
	// - cap.SYS_ADMIN permits the following:
	// - use of bpf_probe_write_user
	// - iteration over the system-wide loaded programs,
	// maps, links BTFs and convert their IDs to file
	// descriptors.
	// - cap.PERFMON is required to load tracing programs.
	// - cap.NET_ADMIN is required to load networking
	// programs.
	BPF

	// CHECKPOINT_RESTORE allows a process to perform checkpoint
	// and restore operations. Also permits
	// explicit PID control via clone3() and
	// also writing to ns_last_pid.
	CHECKPOINT_RESTORE
	)

	var names = map[Value]string{
	CHOWN: "cap_chown",
	DAC_OVERRIDE: "cap_dac_override",
	DAC_READ_SEARCH: "cap_dac_read_search",
	FOWNER: "cap_fowner",
	FSETID: "cap_fsetid",
	KILL: "cap_kill",
	SETGID: "cap_setgid",
	SETUID: "cap_setuid",
	SETPCAP: "cap_setpcap",
	LINUX_IMMUTABLE: "cap_linux_immutable",
	NET_BIND_SERVICE: "cap_net_bind_service",
	NET_BROADCAST: "cap_net_broadcast",
	NET_ADMIN: "cap_net_admin",
	NET_RAW: "cap_net_raw",
	IPC_LOCK: "cap_ipc_lock",
	IPC_OWNER: "cap_ipc_owner",
	SYS_MODULE: "cap_sys_module",
	SYS_RAWIO: "cap_sys_rawio",
	SYS_CHROOT: "cap_sys_chroot",
	SYS_PTRACE: "cap_sys_ptrace",
	SYS_PACCT: "cap_sys_pacct",
	SYS_ADMIN: "cap_sys_admin",
	SYS_BOOT: "cap_sys_boot",
	SYS_NICE: "cap_sys_nice",
	SYS_RESOURCE: "cap_sys_resource",
	SYS_TIME: "cap_sys_time",
	SYS_TTY_CONFIG: "cap_sys_tty_config",
	MKNOD: "cap_mknod",
	LEASE: "cap_lease",
	AUDIT_WRITE: "cap_audit_write",
	AUDIT_CONTROL: "cap_audit_control",
	SETFCAP: "cap_setfcap",
	MAC_OVERRIDE: "cap_mac_override",
	MAC_ADMIN: "cap_mac_admin",
	SYSLOG: "cap_syslog",
	WAKE_ALARM: "cap_wake_alarm",
	BLOCK_SUSPEND: "cap_block_suspend",
	AUDIT_READ: "cap_audit_read",
	PERFMON: "cap_perfmon",
	BPF: "cap_bpf",
	CHECKPOINT_RESTORE: "cap_checkpoint_restore",
	}

	var bits = map[string]Value{
	"cap_chown": CHOWN,
	"cap_dac_override": DAC_OVERRIDE,
	"cap_dac_read_search": DAC_READ_SEARCH,
	"cap_fowner": FOWNER,
	"cap_fsetid": FSETID,
	"cap_kill": KILL,
	"cap_setgid": SETGID,
	"cap_setuid": SETUID,
	"cap_setpcap": SETPCAP,
	"cap_linux_immutable": LINUX_IMMUTABLE,
	"cap_net_bind_service": NET_BIND_SERVICE,
	"cap_net_broadcast": NET_BROADCAST,
	"cap_net_admin": NET_ADMIN,
	"cap_net_raw": NET_RAW,
	"cap_ipc_lock": IPC_LOCK,
	"cap_ipc_owner": IPC_OWNER,
	"cap_sys_module": SYS_MODULE,
	"cap_sys_rawio": SYS_RAWIO,
	"cap_sys_chroot": SYS_CHROOT,
	"cap_sys_ptrace": SYS_PTRACE,
	"cap_sys_pacct": SYS_PACCT,
	"cap_sys_admin": SYS_ADMIN,
	"cap_sys_boot": SYS_BOOT,
	"cap_sys_nice": SYS_NICE,
	"cap_sys_resource": SYS_RESOURCE,
	"cap_sys_time": SYS_TIME,
	"cap_sys_tty_config": SYS_TTY_CONFIG,
	"cap_mknod": MKNOD,
	"cap_lease": LEASE,
	"cap_audit_write": AUDIT_WRITE,
	"cap_audit_control": AUDIT_CONTROL,
	"cap_setfcap": SETFCAP,
	"cap_mac_override": MAC_OVERRIDE,
	"cap_mac_admin": MAC_ADMIN,
	"cap_syslog": SYSLOG,
	"cap_wake_alarm": WAKE_ALARM,
	"cap_block_suspend": BLOCK_SUSPEND,
	"cap_audit_read": AUDIT_READ,
	"cap_perfmon": PERFMON,
	"cap_bpf": BPF,
	"cap_checkpoint_restore": CHECKPOINT_RESTORE,
	}