go-libzfs/zpool.go

572 lines
15 KiB
Go

package zfs
// #include <stdlib.h>
// #include <libzfs.h>
// #include "zpool.h"
// #include "zfs.h"
import "C"
import (
"errors"
"fmt"
"strconv"
)
const (
msgPoolIsNil = "Pool handle not initialized or its closed"
)
type PoolProperties map[PoolProp]string
type ZFSProperties map[ZFSProp]string
// Object represents handler to single ZFS pool
//
/* Pool.Properties map[string]Property
*/
// Map of all ZFS pool properties, changing any of this will not affect ZFS
// pool, for that use SetProperty( name, value string) method of the pool
// object. This map is initial loaded when ever you open or create pool to
// give easy access to listing all available properties. It can be refreshed
// with up to date values with call to (*Pool) ReloadProperties
type Pool struct {
list *C.zpool_list_t
Properties []Property
Features map[string]string
}
// Open ZFS pool handler by name.
// Returns Pool object, requires Pool.Close() to be called explicitly
// for memory cleanup after object is not needed anymore.
func PoolOpen(name string) (pool Pool, err error) {
pool.list = C.zpool_list_open(libzfs_handle, C.CString(name))
if pool.list != nil {
err = pool.ReloadProperties()
return
}
err = LastError()
return
}
// Given a list of directories to search, find and import pool with matching
// name stored on disk.
func PoolImport(name string, searchpaths []string) (pool Pool, err error) {
errPoolList := errors.New("Failed to list pools")
var elem *C.nvpair_t
var config *C.nvlist_t
numofp := len(searchpaths)
cpaths := C.alloc_strings(C.int(numofp))
for i, path := range searchpaths {
C.strings_setat(cpaths, C.int(i), C.CString(path))
}
pools := C.zpool_find_import(libzfs_handle, C.int(numofp), cpaths)
defer C.nvlist_free(pools)
elem = C.nvlist_next_nvpair(pools, elem)
for ; elem != nil; elem = C.nvlist_next_nvpair(pools, elem) {
var cname *C.char
var tconfig *C.nvlist_t
retcode := C.nvpair_value_nvlist(elem, &tconfig)
if retcode != 0 {
err = errPoolList
return
}
retcode = C.nvlist_lookup_string(tconfig,
C.CString(C.ZPOOL_CONFIG_POOL_NAME), &cname)
if retcode != 0 {
err = errPoolList
return
}
oname := C.GoString(cname)
if name == oname {
config = tconfig
break
}
}
if config == nil {
err = errors.New("No pools to import found with name " + name)
return
}
retcode := C.zpool_import(libzfs_handle, config, C.CString(name), nil)
if retcode != 0 {
err = LastError()
return
}
pool, err = PoolOpen(name)
return
}
// Open all active ZFS pools on current system.
// Returns array of Pool handlers, each have to be closed after not needed
// anymore. Call Pool.Close() method.
func PoolOpenAll() (pools []Pool, err error) {
var pool Pool
errcode := C.zpool_list(libzfs_handle, &pool.list)
for pool.list != nil {
err = pool.ReloadProperties()
if err != nil {
return
}
pools = append(pools, pool)
pool.list = C.zpool_next(pool.list)
}
if errcode != 0 {
err = LastError()
}
return
}
func PoolCloseAll(pools []Pool) {
for _, p := range pools {
p.Close()
}
}
// Convert property to name
// ( returns built in string representation of property name).
// This is optional, you can represent each property with string
// name of choice.
func PoolPropertyToName(p PoolProp) (name string) {
if p == PoolNumProps {
return "numofprops"
}
prop := C.zpool_prop_t(p)
name = C.GoString(C.zpool_prop_to_name(prop))
return
}
// Re-read ZFS pool properties and features, refresh Pool.Properties and
// Pool.Features map
func (pool *Pool) ReloadProperties() (err error) {
propList := C.read_zpool_properties(pool.list.zph)
if propList == nil {
err = LastError()
return
}
pool.Properties = make([]Property, PoolNumProps+1)
next := propList
for next != nil {
pool.Properties[next.property] = Property{Value: C.GoString(&(next.value[0])), Source: C.GoString(&(next.source[0]))}
next = C.next_property(next)
}
C.free_properties(propList)
// read features
pool.Features = map[string]string{
"async_destroy": "disabled",
"empty_bpobj": "disabled",
"lz4_compress": "disabled"}
for name, _ := range pool.Features {
pool.GetFeature(name)
}
return
}
// Reload and return single specified property. This also reloads requested
// property in Properties map.
func (pool *Pool) GetProperty(p PoolProp) (prop Property, err error) {
if pool.list != nil {
// First check if property exist at all
if p < PoolPropName || p > PoolNumProps {
err = errors.New(fmt.Sprint("Unknown zpool property: ",
PoolPropertyToName(p)))
return
}
var list C.property_list_t
r := C.read_zpool_property(pool.list.zph, &list, C.int(p))
if r != 0 {
err = LastError()
}
prop.Value = C.GoString(&(list.value[0]))
prop.Source = C.GoString(&(list.source[0]))
pool.Properties[p] = prop
return
}
return prop, errors.New(msgPoolIsNil)
}
// Reload and return single specified feature. This also reloads requested
// feature in Features map.
func (pool *Pool) GetFeature(name string) (value string, err error) {
var fvalue [512]C.char
sname := fmt.Sprint("feature@", name)
r := C.zpool_prop_get_feature(pool.list.zph, C.CString(sname), &(fvalue[0]), 512)
if r != 0 {
err = errors.New(fmt.Sprint("Unknown zpool feature: ", name))
return
}
value = C.GoString(&(fvalue[0]))
pool.Features[name] = value
return
}
// Set ZFS pool property to value. Not all properties can be set,
// some can be set only at creation time and some are read only.
// Always check if returned error and its description.
func (pool *Pool) SetProperty(p PoolProp, value string) (err error) {
if pool.list != nil {
// First check if property exist at all
if p < PoolPropName || p > PoolNumProps {
err = errors.New(fmt.Sprint("Unknown zpool property: ",
PoolPropertyToName(p)))
return
}
r := C.zpool_set_prop(pool.list.zph, C.CString(PoolPropertyToName(p)), C.CString(value))
if r != 0 {
err = LastError()
} else {
// Update Properties member with change made
if _, err = pool.GetProperty(p); err != nil {
return
}
}
return
}
return errors.New(msgPoolIsNil)
}
// Close ZFS pool handler and release associated memory.
// Do not use Pool object after this.
func (pool *Pool) Close() {
C.zpool_list_close(pool.list)
pool.list = nil
}
// Get (re-read) ZFS pool name property
func (pool *Pool) Name() (name string, err error) {
if pool.list == nil {
err = errors.New(msgPoolIsNil)
} else {
name = C.GoString(C.zpool_get_name(pool.list.zph))
pool.Properties[PoolPropName] = Property{Value: name, Source: "none"}
}
return
}
// Get ZFS pool state
// Return the state of the pool (ACTIVE or UNAVAILABLE)
func (pool *Pool) State() (state PoolState, err error) {
if pool.list == nil {
err = errors.New(msgPoolIsNil)
} else {
state = PoolState(C.zpool_read_state(pool.list.zph))
}
return
}
// ZFS virtual device specification
type VDevSpec struct {
Type VDevType
Devices []VDevSpec // groups other devices (e.g. mirror)
Parity uint
Path string
}
func (self *VDevSpec) isGrouping() (grouping bool, mindevs, maxdevs int) {
maxdevs = int(^uint(0) >> 1)
if self.Type == VDevTypeRaidz {
grouping = true
if self.Parity == 0 {
self.Parity = 1
}
if self.Parity > 254 {
self.Parity = 254
}
mindevs = int(self.Parity) + 1
maxdevs = 255
} else if self.Type == VDevTypeMirror {
grouping = true
mindevs = 2
} else if self.Type == VDevTypeLog || self.Type == VDevTypeSpare || self.Type == VDevTypeL2cache {
grouping = true
mindevs = 1
}
return
}
func (self *VDevSpec) isLog() (r C.uint64_t) {
r = 0
if self.Type == VDevTypeLog {
r = 1
}
return
}
func toCPoolProperties(props PoolProperties) (cprops *C.nvlist_t) {
cprops = nil
for prop, value := range props {
name := C.zpool_prop_to_name(C.zpool_prop_t(prop))
r := C.add_prop_list(name, C.CString(value), &cprops, C.boolean_t(1))
if r != 0 {
if cprops != nil {
C.nvlist_free(cprops)
cprops = nil
}
return
}
}
return
}
func toCZFSProperties(props ZFSProperties) (cprops *C.nvlist_t) {
cprops = nil
for prop, value := range props {
name := C.zfs_prop_to_name(C.zfs_prop_t(prop))
r := C.add_prop_list(name, C.CString(value), &cprops, C.boolean_t(0))
if r != 0 {
if cprops != nil {
C.nvlist_free(cprops)
cprops = nil
}
return
}
}
return
}
func buildVDevSpec(root *C.nvlist_t, rtype VDevType, vdevs []VDevSpec,
props PoolProperties) (err error) {
count := len(vdevs)
if count == 0 {
return
}
childrens := C.nvlist_alloc_array(C.int(count))
if childrens == nil {
err = errors.New("No enough memory")
return
}
defer C.nvlist_free_array(childrens)
spares := C.nvlist_alloc_array(C.int(count))
if childrens == nil {
err = errors.New("No enough memory")
return
}
nspares := 0
defer C.nvlist_free_array(spares)
l2cache := C.nvlist_alloc_array(C.int(count))
if childrens == nil {
err = errors.New("No enough memory")
return
}
nl2cache := 0
defer C.nvlist_free_array(l2cache)
for i, vdev := range vdevs {
grouping, mindevs, maxdevs := vdev.isGrouping()
var child *C.nvlist_t = nil
// fmt.Println(vdev.Type)
if r := C.nvlist_alloc(&child, C.NV_UNIQUE_NAME, 0); r != 0 {
err = errors.New("Failed to allocate vdev")
return
}
vcount := len(vdev.Devices)
if vcount < mindevs || vcount > maxdevs {
err = errors.New(fmt.Sprintf(
"Invalid vdev specification: %s supports no less than %d or more than %d devices", vdev.Type, mindevs, maxdevs))
return
}
if r := C.nvlist_add_string(child, C.CString(C.ZPOOL_CONFIG_TYPE),
C.CString(string(vdev.Type))); r != 0 {
err = errors.New("Failed to set vdev type")
return
}
if r := C.nvlist_add_uint64(child, C.CString(C.ZPOOL_CONFIG_IS_LOG),
vdev.isLog()); r != 0 {
err = errors.New("Failed to allocate vdev (is_log)")
return
}
if grouping {
if vdev.Type == VDevTypeRaidz {
r := C.nvlist_add_uint64(child,
C.CString(C.ZPOOL_CONFIG_NPARITY),
C.uint64_t(mindevs-1))
if r != 0 {
err = errors.New("Failed to allocate vdev (parity)")
return
}
}
if err = buildVDevSpec(child, vdev.Type, vdev.Devices,
props); err != nil {
return
}
} else {
// if vdev.Type == VDevTypeDisk {
if r := C.nvlist_add_uint64(child,
C.CString(C.ZPOOL_CONFIG_WHOLE_DISK), 1); r != 0 {
err = errors.New("Failed to allocate vdev child (whdisk)")
return
}
// }
if len(vdev.Path) > 0 {
if r := C.nvlist_add_string(
child, C.CString(C.ZPOOL_CONFIG_PATH),
C.CString(vdev.Path)); r != 0 {
err = errors.New("Failed to allocate vdev child (type)")
return
}
ashift, _ := strconv.Atoi(props[PoolPropAshift])
if ashift > 0 {
if r := C.nvlist_add_uint64(child,
C.CString(C.ZPOOL_CONFIG_ASHIFT),
C.uint64_t(ashift)); r != 0 {
err = errors.New("Failed to allocate vdev child (ashift)")
return
}
}
}
if vdev.Type == VDevTypeSpare {
C.nvlist_array_set(spares, C.int(nspares), child)
nspares++
count--
continue
} else if vdev.Type == VDevTypeL2cache {
C.nvlist_array_set(l2cache, C.int(nl2cache), child)
nl2cache++
count--
continue
}
}
C.nvlist_array_set(childrens, C.int(i), child)
}
if count > 0 {
if r := C.nvlist_add_nvlist_array(root,
C.CString(C.ZPOOL_CONFIG_CHILDREN), childrens,
C.uint_t(count)); r != 0 {
err = errors.New("Failed to allocate vdev children")
return
}
// fmt.Println("childs", root, count, rtype)
// debug.PrintStack()
}
if nl2cache > 0 {
if r := C.nvlist_add_nvlist_array(root,
C.CString(C.ZPOOL_CONFIG_L2CACHE), l2cache,
C.uint_t(nl2cache)); r != 0 {
err = errors.New("Failed to allocate vdev cache")
return
}
}
if nspares > 0 {
if r := C.nvlist_add_nvlist_array(root,
C.CString(C.ZPOOL_CONFIG_SPARES), spares,
C.uint_t(nspares)); r != 0 {
err = errors.New("Failed to allocate vdev spare")
return
}
// fmt.Println("spares", root, count)
}
return
}
// Create ZFS pool per specs, features and properties of pool and root dataset
func PoolCreate(name string, vdevs []VDevSpec, features map[string]string,
props PoolProperties, fsprops ZFSProperties) (pool Pool, err error) {
// create root vdev nvroot
var nvroot *C.nvlist_t = nil
if r := C.nvlist_alloc(&nvroot, C.NV_UNIQUE_NAME, 0); r != 0 {
err = errors.New("Failed to allocate root vdev")
return
}
if r := C.nvlist_add_string(nvroot, C.CString(C.ZPOOL_CONFIG_TYPE),
C.CString(string(VDevTypeRoot))); r != 0 {
err = errors.New("Failed to allocate root vdev")
return
}
defer C.nvlist_free(nvroot)
// Now we need to build specs (vdev hierarchy)
if err = buildVDevSpec(nvroot, VDevTypeRoot, vdevs, props); err != nil {
return
}
// convert properties
cprops := toCPoolProperties(props)
if cprops != nil {
defer C.nvlist_free(cprops)
} else if len(props) > 0 {
err = errors.New("Failed to allocate pool properties")
return
}
cfsprops := toCZFSProperties(fsprops)
if cfsprops != nil {
defer C.nvlist_free(cfsprops)
} else if len(fsprops) > 0 {
err = errors.New("Failed to allocate FS properties")
return
}
for fname, fval := range features {
sfname := fmt.Sprintf("feature@%s", fname)
r := C.add_prop_list(C.CString(sfname), C.CString(fval), &cprops,
C.boolean_t(1))
if r != 0 {
if cprops != nil {
C.nvlist_free(cprops)
cprops = nil
}
return
}
}
// Create actual pool then open
if r := C.zpool_create(libzfs_handle, C.CString(name), nvroot,
cprops, cfsprops); r != 0 {
err = LastError()
return
}
pool, err = PoolOpen(name)
return
}
// Get pool status. Let you check if pool healthy.
func (pool *Pool) Status() (status PoolStatus, err error) {
var msgid *C.char
var reason C.zpool_status_t
var errata C.zpool_errata_t
if pool.list == nil {
err = errors.New(msgPoolIsNil)
return
}
reason = C.zpool_get_status(pool.list.zph, &msgid, &errata)
status = PoolStatus(reason)
return
}
// Destroy the pool. It is up to the caller to ensure that there are no
// datasets left in the pool. logStr is optional if specified it is
// appended to ZFS history
func (pool *Pool) Destroy(logStr string) (err error) {
if pool.list == nil {
err = errors.New(msgPoolIsNil)
return
}
retcode := C.zpool_destroy(pool.list.zph, C.CString(logStr))
if retcode != 0 {
err = LastError()
}
return
}
// Exports the pool from the system.
// Before exporting the pool, all datasets within the pool are unmounted.
// A pool can not be exported if it has a shared spare that is currently
// being used.
func (pool *Pool) Export(force bool, log string) (err error) {
var force_t C.boolean_t = 0
if force {
force_t = 1
}
if rc := C.zpool_export(pool.list.zph, force_t, C.CString(log)); rc != 0 {
err = LastError()
}
return
}
// Hard force
func (pool *Pool) ExportForce(log string) (err error) {
if rc := C.zpool_export_force(pool.list.zph, C.CString(log)); rc != 0 {
err = LastError()
}
return
}