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man pages section 1M: System Administration Commands Oracle Solaris 11 Express 11/10 |
System Administration Commands - Part 1
System Administration Commands - Part 2
- set up zone configuration
zonecfg -z zonename
zonecfg -z zonename subcommand
zonecfg -z zonename -f command_file
zonecfg help
The zonecfg utility creates, modifies, and lists the configuration of a zone. The creation and modification functions are only available to authorized users and require that the process is executed with an effective user ID of root. Otherwise it runs in read-only mode.
A zone's configuration consists of a number of resources and properties.
To simplify the user interface, zonecfg uses the concept of a scope. The default scope is global.
The following synopsis of the zonecfg command is for interactive usage:
zonecfg -z zonename subcommand
Parameters changed through zonecfg do not affect a running zone. The zone must be rebooted for the changes to take effect.
In addition to creating and modifying a zone, the zonecfg utility can also be used to persistently specify the resource management settings for the global zone.
In the following text, “rctl” is used as an abbreviation for “resource control”. See resource_controls(5).
Every zone is configured with an associated brand. The brand determines the user-level environment used within the zone, as well as various behaviors for the zone when it is installed, boots, or is shutdown. Once a zone has been installed the brand cannot be changed. The default brand is determined by the installed distribution in the global zone. Some brands do not support all of the zonecfg properties and resources. See the brand-specific man page for more details on each brand. For an overview of brands, see the brands(5) man page.
The following resource types are supported:
Generic attribute.
Limits for CPU usage.
Limits for physical, swap, and locked memory.
ZFS dataset.
Subset of the system's processors dedicated to this zone while it is running.
Device.
file-system
Network interface.
Delegated administrator.
Resource control.
Previous releases of Solaris offered the notion of sparse root zones. This functionality was intimately associated with the SVr4 packaging system and intended to save disk space and reduce administrative effort.
The new packaging system, IPS, provides more flexibility when choosing which packages to install in a zone. This, along with advances in file system technology (notable among which is ZFS deduplication), means that it was most sensible to remove sparse root zones. The benefits of sparse root zones are provided for all zones by means of the combination of IPS packaging and file system advances.
Each resource type has one or more properties. There are also some global properties, that is, properties of the configuration as a whole, rather than of some particular resource.
The following properties are supported:
zonename
zonepath
autoboot
bootargs
pool
limitpriv
brand
cpu-shares
hostid
max-lwps
max-msg-ids
max-processes
max-sem-ids
max-shm-ids
max-shm-memory
scheduling-class
fs-allowed
dir, special, raw, type, options
address, allowed-address, physical, defrouter
match
name, value
name, type, value
name
ncpus, importance
physical, swap, locked
ncpus
user, auths
As for the property values which are paired with these names, they are either simple, complex, or lists. The type allowed is property-specific. Simple values are strings, optionally enclosed within quotation marks. Complex values have the syntax:
(<name>=<value>,<name>=<value>,...)
where each <value> is simple, and the <name> strings are unique within a given property. Lists have the syntax:
[<value>,...]
where each <value> is either simple or complex. A list of a single value (either simple or complex) is equivalent to specifying that value without the list syntax. That is, “foo” is equivalent to “[foo]”. A list can be empty (denoted by “[]”).
In interpreting property values, zonecfg accepts regular expressions as specified in fnmatch(5). See EXAMPLES.
The property types are described as follows:
The name of the zone.
Path to zone's file system.
Boolean indicating that a zone should be booted automatically at system boot. Note that if the zones service is disabled, the zone will not autoboot, regardless of the setting of this property. You enable the zones service with a svcadm command, such as:
# svcadm enable svc:/system/zones:default
Replace enable with disable to disable the zones service. See svcadm(1M).
Arguments (options) to be passed to the zone bootup, unless options are supplied to the “zoneadm boot” command, in which case those take precedence. The valid arguments are described in zoneadm(1M).
Name of the resource pool that this zone must be bound to when booted. This property is incompatible with the dedicated-cpu resource.
The maximum set of privileges any process in this zone can obtain. The property should consist of a comma-separated privilege set specification as described in priv_str_to_set(3C). Privileges can be excluded from the resulting set by preceding their names with a dash (-) or an exclamation point (!). The special privilege string “zone” is not supported in this context. If the special string “default” occurs as the first token in the property, it expands into a safe set of privileges that preserve the resource and security isolation described in zones(5). A missing or empty property is equivalent to this same set of safe privileges.
The system administrator must take extreme care when configuring privileges for a zone. Some privileges cannot be excluded through this mechanism as they are required in order to boot a zone. In addition, there are certain privileges which cannot be given to a zone as doing so would allow processes inside a zone to unduly affect processes in other zones. zoneadm(1M) indicates when an invalid privilege has been added or removed from a zone's privilege set when an attempt is made to either “boot” or “ready” the zone.
See privileges(5) for a description of privileges. The command “ppriv -l” (see ppriv(1)) produces a list of all Solaris privileges. You can specify privileges as they are displayed by ppriv. In privileges(5), privileges are listed in the form PRIV_privilege_name. For example, the privilege sys_time, as you would specify it in this property, is listed in privileges(5) as PRIV_SYS_TIME.
The zone's brand type.
A zone can either share the IP instance with the global zone, which is the default, or have its own exclusive instance of IP.
This property takes the values shared and exclusive.
A zone can emulate a 32-bit host identifier to ease system consolidation. A zone's hostid property is empty by default, meaning that the zone does not emulate a host identifier. Zone host identifiers must be hexadecimal values between 0 and FFFFFFFE. A 0x or 0X prefix is optional. Both uppercase and lowercase hexadecimal digits are acceptable.
A comma-separated list of additional file systems that can be mounted within the zone; for example, ufs,pcfs. By default, only hsfs(7FS) and network file systems can be mounted.
This property does not apply to file systems mounted into the zone by means of add fs or add dataset.
 | Caution - Allowing filesystem mounts other than the default might allow the zone administrator to compromise the system with a bogus filesystem image and is not supported. |
Values needed to determine how, where, and so forth to mount file systems. See mount(1M), mount(2), fsck(1M), and vfstab(4).
The network address and physical interface name of the network interface. The network address is one of:
a valid IPv4 address, optionally followed by “/” and a prefix length;
a valid IPv6 address, which must be followed by “/” and a prefix length;
a host name which resolves to an IPv4 address.
Note that host names that resolve to IPv6 addresses are not supported.
The physical interface name is the network interface name.
The value for the optional default router is specified similarly to the network address except that it must not be followed by a / (slash) and a network prefix length. To enable correct use of the defrouter functionality, the zones that use the property must be on a different subnet from the subnet on which the global zone resides. Also, each zone (or set of zones) that uses a different defrouter setting must be on a different subnet.
A zone can be configured to be either exclusive-IP or shared-IP. For a shared-IP zone, you must set both the physical and address properties; setting the default router is optional. The interface specified in the physical property must be plumbed in the global zone prior to booting the non-global zone. However, if the interface is not used by the global zone, it should be configured down in the global zone, and the default router for the interface should be specified here. The allowed-address property cannot be set for a shared-IP zone.
For an exclusive-IP zone, the physical property must be set and the address and default router, and address properties cannot be set. Optionally, the set of IP addresses that the exclusive-IP zone can use might be constrained by specifying the allowed-address property. If allowed-address has not been specified, then the exclusive-IP zone can use any IP address on the associated physical interface for the net resource. Otherwise, when allowed-address is specified, the exclusive-IP zone cannot use IP addresses that are not in the allowed-address list for the physical adddress. In addition, when the allowed-address list has been populated, the defrouter property can also be optionally specified. The interface specified for the physical property must not be in use in the global zone. If an allowed-address and default router are specified by means of zonecfg, these will be applied to the interface when it is enabled by means of ipadm(1M) in the non-global, exclusive-IP zone, typically during zone boot. The non-global exclusive-IP zone will not be able to apply any other addresses to that interface, nor will it be able to transmit packets with a different source address for the specified IP version. A default router set up by means of zonecfg cannot be persistently deleted from within the non-global exclusive-IP zone using the -p flag with route(1M).
Note that a single datalink cannot be shared among multiple exclusive-IP zones.
Device name to match.
The name and priv/limit/action triple of a resource control. See prctl(1) and rctladm(1M). The preferred way to set rctl values is to use the global property name associated with a specific rctl.
The name, type and value of a generic attribute. The type must be one of int, uint, boolean or string, and the value must be of that type. uint means unsigned , that is, a non-negative integer.
The name of a ZFS dataset to be accessed from within the zone. See zfs(1M).
The number of Fair Share Scheduler (FSS) shares to allocate to this zone. This property is incompatible with the dedicated-cpu resource. This property is the preferred way to set the zone.cpu-shares rctl.
The maximum number of LWPs simultaneously available to this zone. This property is the preferred way to set the zone.max-lwps rctl.
The maximum number of message queue IDs allowed for this zone. This property is the preferred way to set the zone.max-msg-ids rctl.
The maximum number of process table slots simultaneously available to this zone. This property is the preferred way to set the zone.max-processes rctl. Setting this property will implicitly set the value of the max-lwps property to 10 times the number of process slots unless the max-lwps property has been set explicitly.
The maximum number of semaphore IDs allowed for this zone. This property is the preferred way to set the zone.max-sem-ids rctl.
The maximum number of shared memory IDs allowed for this zone. This property is the preferred way to set the zone.max-shm-ids rctl.
The maximum amount of shared memory allowed for this zone. This property is the preferred way to set the zone.max-shm-memory rctl. A scale (K, M, G, T) can be applied to the value for this number (for example, 1M is one megabyte).
Specifies the scheduling class used for processes running in a zone. When this property is not specified, the scheduling class is established as follows:
If the cpu-shares property or equivalent rctl is set, the scheduling class FSS is used.
If neither cpu-shares nor the equivalent rctl is set and the zone's pool property references a pool that has a default scheduling class, that class is used.
Under any other conditions, the system default scheduling class is used.
The number of CPUs that should be assigned for this zone's exclusive use. The zone will create a pool and processor set when it boots. See pooladm(1M) and poolcfg(1M) for more information on resource pools. The ncpu property can specify a single value or a range (for example, 1-4) of processors. The importance property is optional; if set, it will specify the pset.importance value for use by poold(1M). If this resource is used, there must be enough free processors to allocate to this zone when it boots or the zone will not boot. The processors assigned to this zone will not be available for the use of the global zone or other zones. This resource is incompatible with both the pool and cpu-shares properties. Only a single instance of this resource can be added to the zone.
The caps on the memory that can be used by this zone. A scale (K, M, G, T) can be applied to the value for each of these numbers (for example, 1M is one megabyte). Each of these properties is optional but at least one property must be set when adding this resource. Only a single instance of this resource can be added to the zone. The physical property sets the max-rss for this zone. This will be enforced by rcapd(1M) running in the global zone. The swap property is the preferred way to set the zone.max-swap rctl. The locked property is the preferred way to set the zone.max-locked-memory rctl.
Sets a limit on the amount of CPU time that can be used by a zone. The unit used translates to the percentage of a single CPU that can be used by all user threads in a zone, expressed as a fraction (for example, .75) or a mixed number (whole number and fraction, for example, 1.25). An ncpu value of 1 means 100% of a CPU, a value of 1.25 means 125%, .75 mean 75%, and so forth. When projects within a capped zone have their own caps, the minimum value takes precedence.
The capped-cpu property is an alias for zone.cpu-cap resource control and is related to the zone.cpu-cap resource control. See resource_controls(5).
Delegates zone administrative authorizations to the specified user or role. The user must correspond to a valid local account. The allowed values for auths are:
Allows authenticated use of zlogin(1) into this zone.
Allows normal management of the configured zone.
Allows the use of the specified zone as a source from which to clone a new zone.
The following table summarizes resources, property-names, and types:
resource property-name type
(global) zonename simple
(global) zonepath simple
(global) autoboot simple
(global) bootargs simple
(global) pool simple
(global) limitpriv simple
(global) brand simple
(global) ip-type simple
(global) hostid simple
(global) cpu-shares simple
(global) max-lwps simple
(global) max-msg-ids simple
(global) max-sem-ids simple
(global) max-shm-ids simple
(global) max-shm-memory simple
(global) scheduling-class simple
(global) fs-allowed list of simple
fs dir simple
special simple
raw simple
type simple
options list of simple
net address simple
physical simple
device match simple
rctl name simple
value list of complex
attr name simple
type simple
value simple
dataset name simple
dedicated-cpu ncpus simple or range
importance simple
capped-memory physical simple with scale
swap simple with scale
locked simple with scale
capped-cpu ncpus simple
admin user simple
auths list of simpleTo further specify things, the breakdown of the complex property “value” of the “rctl” resource type, it consists of three name/value pairs, the names being “priv”, “limit” and “action”, each of which takes a simple value. The “name” property of an “attr” resource is syntactically restricted in a fashion similar but not identical to zone names: it must begin with an alphanumeric, and can contain alphanumerics plus the hyphen (-), underscore (_), and dot (.) characters. Attribute names beginning with “zone” are reserved for use by the system. Finally, the “autoboot” global property must have a value of “true“ or “false”.
Using the kernel statistics (kstat(3KSTAT)) module caps, the system maintains information for all capped projects and zones. You can access this information by reading kernel statistics (kstat(3KSTAT)), specifying caps as the kstat module name. The following command displays kernel statistics for all active CPU caps:
# kstat caps::'/cpucaps/'
A kstat(1M) command running in a zone displays only CPU caps relevant for that zone and for projects in that zone. See EXAMPLES.
The following are cap-related arguments for use with kstat(1M):
The kstat module.
kstat class, for use with the kstat -c option.
kstat name, for use with the kstat -n option. id is the project or zone identifier.
The following fields are displayed in response to a kstat(1M) command requesting statistics for all CPU caps.
In this usage of kstat, this field will have the value caps.
As described above, cpucaps_project_id or cpucaps_zone_id
Total time, in seconds, spent above the cap.
Total time, in seconds, spent below the cap.
Maximum observed CPU usage.
Number of threads on cap wait queue.
Current aggregated CPU usage for all threads belonging to a capped project or zone, in terms of a percentage of a single CPU.
The cap value, in terms of a percentage of a single CPU.
Name of the zone for which statistics are displayed.
See EXAMPLES for sample output from a kstat command.
The following options are supported:
Specify the name of zonecfg command file. command_file is a text file of zonecfg subcommands, one per line.
Specify the name of a zone. Zone names are case sensitive. Zone names must begin with an alphanumeric character and can contain alphanumeric characters, the underscore (_) the hyphen (-), and the dot (.). The name global and all names beginning with SUNW are reserved and cannot be used.
You can use the add and select subcommands to select a specific resource, at which point the scope changes to that resource. The end and cancel subcommands are used to complete the resource specification, at which time the scope is reverted back to global. Certain subcommands, such as add, remove and set, have different semantics in each scope.
zonecfg supports a semicolon-separated list of subcommands. For example:
# zonecfg -z myzone "add net; set physical=myvnic; end"
Subcommands which can result in destructive actions or loss of work have an -F option to force the action. If input is from a terminal device, the user is prompted when appropriate if such a command is given without the -F option otherwise, if such a command is given without the -F option, the action is disallowed, with a diagnostic message written to standard error.
The following subcommands are supported:
In the global scope, begin the specification for a given resource type. The scope is changed to that resource type.
In the resource scope, add a property of the given name with the given value. The syntax for property values varies with different property types. In general, it is a simple value or a list of simple values enclosed in square brackets, separated by commas ([foo,bar,baz]). See PROPERTIES.
End the resource specification and reset scope to global. Abandons any partially specified resources. cancel is only applicable in the resource scope.
Clear the value for the property.
Commit the current configuration from memory to stable storage. The configuration must be committed to be used by zoneadm. Until the in-memory configuration is committed, you can remove changes with the revert subcommand. The commit operation is attempted automatically upon completion of a zonecfg session. Since a configuration must be correct to be committed, this operation automatically does a verify.
Create an in-memory configuration for the specified zone. Use create to begin to configure a new zone. See commit for saving this to stable storage.
If you are overwriting an existing configuration, specify the -F option to force the action. Specify the -t template option to create a configuration identical to template, where template is the name of a configured zone.
Use the -a path option to facilitate configuring a detached zone on a new host. The path parameter is the zonepath location of a detached zone that has been moved on to this new host. Once the detached zone is configured, it should be installed using the “zoneadm attach” command (see zoneadm(1M)). All validation of the new zone happens during the attach process, not during zone configuration.
Use the -b option to create a blank configuration. Without arguments, create applies the Sun default settings.
Delete the specified configuration from memory and stable storage. This action is instantaneous, no commit is necessary. A deleted configuration cannot be reverted.
Specify the -F option to force the action.
End the resource specification. This subcommand is only applicable in the resource scope. zonecfg checks to make sure the current resource is completely specified. If so, it is added to the in-memory configuration (see commit for saving this to stable storage) and the scope reverts to global. If the specification is incomplete, it issues an appropriate error message.
Print configuration to standard output. Use the -f option to print the configuration to output-file. This option produces output in a form suitable for use in a command file.
Print general help or help about given topic.
Display information about the current configuration. If resource-type is specified, displays only information about resources of the relevant type. If any property-name value pairs are specified, displays only information about resources meeting the given criteria. In the resource scope, any arguments are ignored, and info displays information about the resource which is currently being added or modified.
In the global scope, removes the specified resource. The [] syntax means 0 or more of whatever is inside the square braces. If you want only to remove a single instance of the resource, you must specify enough property name-value pairs for the resource to be uniquely identified. If no property name-value pairs are specified, all instances will be removed. If there is more than one pair is specified, a confirmation is required, unless you use the -F option.
Select the resource of the given type which matches the given property-name property-value pair criteria, for modification. This subcommand is applicable only in the global scope. The scope is changed to that resource type. The {} syntax means 1 or more of whatever is inside the curly braces. You must specify enough property -name property-value pairs for the resource to be uniquely identified.
Set a given property name to the given value. Some properties (for example, zonename and zonepath) are global while others are resource-specific. This subcommand is applicable in both the global and resource scopes.
Verify the current configuration for correctness:
All resources have all of their required properties specified.
A zonepath is specified.
Revert the configuration back to the last committed state. The -F option can be used to force the action.
Exit the zonecfg session. A commit is automatically attempted if needed. You can also use an EOF character to exit zonecfg. The -F option can be used to force the action.
Example 1 Creating the Environment for a New Zone
In the following example, zonecfg creates the environment for a new zone. /usr/local is loopback mounted from the global zone into /opt/local. /opt/sfw is loopback mounted from the global zone, three logical network interfaces are added, and a limit on the number of fair-share scheduler (FSS) CPU shares for a zone is set using the rctl resource type. The example also shows how to select a given resource for modification.
example# zonecfg -z myzone3 my-zone3: No such zone configured Use 'create' to begin configuring a new zone. zonecfg:myzone3> create zonecfg:myzone3> set zonepath=/export/home/my-zone3 zonecfg:myzone3> set autoboot=true zonecfg:myzone3> add fs zonecfg:myzone3:fs> set dir=/usr/local zonecfg:myzone3:fs> set special=/opt/local zonecfg:myzone3:fs> set type=lofs zonecfg:myzone3:fs> add options [ro,nodevices] zonecfg:myzone3:fs> end zonecfg:myzone3> add fs zonecfg:myzone3:fs> set dir=/mnt zonecfg:myzone3:fs> set special=/dev/dsk/c0t0d0s7 zonecfg:myzone3:fs> set raw=/dev/rdsk/c0t0d0s7 zonecfg:myzone3:fs> set type=ufs zonecfg:myzone3:fs> end zonecfg:myzone3> add fs zonecfg:myzone3:fs> set dir=/opt/sfw zonecfg:myzone3:fs> set special=/opt/sfw zonecfg:myzone3:fs> set type=lofs zonecfg:myzone3:fs> add options [ro,nodevices] zonecfg:myzone3:fs> end zonecfg:myzone3> add net zonecfg:myzone3:net> set address=192.168.0.1/24 zonecfg:myzone3:net> set physical=eri0 zonecfg:myzone3:net> end zonecfg:myzone3> add net zonecfg:myzone3:net> set address=192.168.1.2/24 zonecfg:myzone3:net> set physical=eri0 zonecfg:myzone3:net> end zonecfg:myzone3> add net zonecfg:myzone3:net> set address=192.168.2.3/24 zonecfg:myzone3:net> set physical=eri0 zonecfg:myzone3:net> end zonecfg:my-zone3> set cpu-shares=5 zonecfg:my-zone3> add capped-memory zonecfg:my-zone3:capped-memory> set physical=50m zonecfg:my-zone3:capped-memory> set swap=100m zonecfg:my-zone3:capped-memory> end zonecfg:myzone3> exit
Example 2 Creating an Exclusive-IP Zone
The following example creates a zone that is granted exclusive access to bge1 and bge33000 and that is isolated at the IP layer from the other zones configured on the system.
The IP addresses and routing is configured inside the new zone using sysidtool(1M).
example# zonecfg -z excl excl: No such zone configured Use 'create' to begin configuring a new zone zonecfg:excl> create zonecfg:excl> set zonepath=/export/zones/excl zonecfg:excl> set ip-type=exclusive zonecfg:excl> add net zonecfg:excl:net> set physical=bge1 zonecfg:excl:net> end zonecfg:excl> add net zonecfg:excl:net> set physical=bge33000 zonecfg:excl:net> end zonecfg:excl> exit
Example 3 Associating a Zone with a Resource Pool
The following example shows how to associate an existing zone with an existing resource pool:
example# zonecfg -z myzone zonecfg:myzone> set pool=mypool zonecfg:myzone> exit
For more information about resource pools, see pooladm(1M) and poolcfg(1M).
Example 4 Changing the Name of a Zone
The following example shows how to change the name of an existing zone:
example# zonecfg -z myzone zonecfg:myzone> set zonename=myzone2 zonecfg:myzone2> exit
Example 5 Changing the Privilege Set of a Zone
The following example shows how to change the set of privileges an existing zone's processes will be limited to the next time the zone is booted. In this particular case, the privilege set will be the standard safe set of privileges a zone normally has along with the privilege to change the system date and time:
example# zonecfg -z myzone zonecfg:myzone> set limitpriv="default,sys_time" zonecfg:myzone2> exit
Example 6 Setting the zone.cpu-shares Property for the Global Zone
The following command sets the zone.cpu-shares property for the global zone:
example# zonecfg -z global zonecfg:global> set cpu-shares=5 zonecfg:global> exit
Example 7 Using Pattern Matching
The following commands illustrate zonecfg support for pattern matching. In the zone flexlm, enter:
zonecfg:flexlm> add device zonecfg:flexlm:device> set match="/dev/cua/a00[2-5]" zonecfg:flexlm:device> end
In the global zone, enter:
global# ls /dev/cua a a000 a001 a002 a003 a004 a005 a006 a007 b
In the zone flexlm, enter:
flexlm# ls /dev/cua a002 a003 a004 a005
Example 8 Setting a Cap for a Zone to Three CPUs
The following sequence uses the zonecfg command to set the CPU cap for a zone to three CPUs.
zonecfg:myzone> add capped-cpu zonecfg:myzone>capped-cpu> set ncpus=3 zonecfg:myzone>capped-cpu>capped-cpu> end
The preceding sequence, which uses the capped-cpu property, is equivalent to the following sequence, which makes use of the zone.cpu-cap resource control.
zonecfg:myzone> add rctl zonecfg:myzone:rctl> set name=zone.cpu-cap zonecfg:myzone:rctl> add value (priv=privileged,limit=300,action=none) zonecfg:myzone:rctl> end
Example 9 Using kstat to Monitor CPU Caps
The following command displays information about all CPU caps.
# kstat -n /cpucaps/
module: caps instance: 0
name: cpucaps_project_0 class: project_caps
above_sec 0
below_sec 2157
crtime 821.048183159
maxusage 2
nwait 0
snaptime 235885.637253027
usage 0
value 18446743151372347932
zonename global
module: caps instance: 0
name: cpucaps_project_1 class: project_caps
above_sec 0
below_sec 0
crtime 225339.192787265
maxusage 5
nwait 0
snaptime 235885.637591677
usage 5
value 18446743151372347932
zonename global
module: caps instance: 0
name: cpucaps_project_201 class: project_caps
above_sec 0
below_sec 235105
crtime 780.37961782
maxusage 100
nwait 0
snaptime 235885.637789687
usage 43
value 100
zonename global
module: caps instance: 0
name: cpucaps_project_202 class: project_caps
above_sec 0
below_sec 235094
crtime 791.72983782
maxusage 100
nwait 0
snaptime 235885.637967512
usage 48
value 100
zonename global
module: caps instance: 0
name: cpucaps_project_203 class: project_caps
above_sec 0
below_sec 235034
crtime 852.104401481
maxusage 75
nwait 0
snaptime 235885.638144304
usage 47
value 100
zonename global
module: caps instance: 0
name: cpucaps_project_86710 class: project_caps
above_sec 22
below_sec 235166
crtime 698.441717859
maxusage 101
nwait 0
snaptime 235885.638319871
usage 54
value 100
zonename global
module: caps instance: 0
name: cpucaps_zone_0 class: zone_caps
above_sec 100733
below_sec 134332
crtime 821.048177123
maxusage 207
nwait 2
snaptime 235885.638497731
usage 199
value 200
zonename global
module: caps instance: 1
name: cpucaps_project_0 class: project_caps
above_sec 0
below_sec 0
crtime 225360.256448422
maxusage 7
nwait 0
snaptime 235885.638714404
usage 7
value 18446743151372347932
zonename test_001
module: caps instance: 1
name: cpucaps_zone_1 class: zone_caps
above_sec 2
below_sec 10524
crtime 225360.256440278
maxusage 106
nwait 0
snaptime 235885.638896443
usage 7
value 100
zonename test_001Example 10 Displaying CPU Caps for a Specific Zone or Project
Using the kstat -c and -i options, you can display CPU caps for a specific zone or project, as below. The first command produces a display for a specific project, the second for the same project within zone 1.
# kstat -c project_caps # kstat -c project_caps -i 1
Example 11 Delegating Zone Administrative Rights
The following example shows how to assign administrative rights for the current zone to a role.
example# zonecfg -z myzone zonecfg:myzone> add admin zonecfg:myzone:admin> set user=zadmin zonecfg:myzone:admin> set auths=login,manage zonecfg:myzone:admin> end zonecfg:myzone> commit
The result of executing these commands would be an updated entry in the RBAC user_attr(4) database, similar to the following:
zadmin::::type=role;\ auths=solaris.zone.login/myzone,solaris.zone.manage/myzone;profiles=Zone Management
The following exit values are returned:
Successful completion.
An error occurred.
Invalid usage.
See attributes(5) for descriptions of the following attributes:
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ppriv(1), prctl(1), zlogin(1), ipadm(1M), kstat(1M), mount(1M), pooladm(1M), poolcfg(1M), poold(1M), rcapd(1M), rctladm(1M), route(1M), svcadm(1M), sysidtool(1M), zfs(1M), zoneadm(1M), priv_str_to_set(3C), kstat(3KSTAT), user_attr(4), vfstab(4), attributes(5), brands(5), fnmatch(5), privileges(5), rbac(5), resource_controls(5), zones(5), hsfs(7FS), uscsi(7I)
All character data used by zonecfg must be in US-ASCII encoding.
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